|
|
|
| Quantity allocation optimization of hot metal ladles in ironmaking-steelmaking interface based on Flexsim |
| FENG Yu-wei, HAN Wei-gang, ZHANG Yu-zhu, HU Chang-qing, LONG Yue |
| School of Metallurgy and Energy, North China University of Science and Technology, Tangshan 063210, Hebei, China |
|
|
|
|
Abstract In order to optimize the number of hot metal ladles and improve the practical results of ironmaking-steelmaking interface technology,a Flexsim-based method for quantity allocation optimization of hot metal ladles in ironmaking-steelmaking section was proposed. The basic idea of which was to establish and apply the Flexsim simulation model of ironmaking-steelmaking interface and hot metal tank turnover process,to investigate whether the number of hot metal ladles under the blast furnace met the production requirements under different hot metal ladle allocation schemes,so as to determine the optimal scheme of hot metal tank number allocation. The case study of steel plant C showed that the optimal quantity of hot metal ladles in ironmaking-steelmaking was 24 according to the existing production conditions and the requirement that the number of hot metal ladles under each blast furnace taphole was not less than 2.
|
|
Received: 15 March 2021
Published: 12 August 2021
|
|
|
|
[1] 殷瑞钰. 冶金流程工程学[M]. 2版. 北京:冶金工业出版社,2009. (YIN Rui-yu. Metallurgical Process Engineering[M]. 2nd ed. Beijing:Metallurgical Industry Press,2009.)
[2] 殷瑞钰. 冶金流程集成理论与方法[M]. 北京:冶金工业出版社,2013. (YIN Rui-yu. Theory and Method of Metallurgical Process Integration[M]. Beijing:Metallurgical Industry Press,2013.)
[3] 王海风,郦秀萍,周继程,等. 钢铁工业节能技术发展现状及趋势[J]. 冶金能源,2018,37(4):3.(WANG Hai-feng,LI Xiu-ping,ZHOU Ji-cheng,et al. Status and development trend of energy saving technology of Chinese steel industry[J]. Energy for Metallurgy Industry,2018,37(4):3.)
[4] 贾启超,刘常鹏,孙金铎,等. 高炉-转炉界面不同运输方式的探讨[J]. 冶金能源,2015,34(3):11.(JIA Qi-chao,LIU Chang-peng,SUN Jin-duo,et al. Discussion on different ways to transport hot metal on BF/BOF[J]. Energy for Metallurgy Industry,2015,34(3):11.)
[5] 杜涛,蔡九菊,李亚军,等. 炼铁-炼钢界面温降与节能模式分析[J]. 钢铁,2008,43(12):83. (DU Tao,CAI Jiu-ju,LI Ya-jun,et al. Analysis of hot metal temperature drop and energy-saving mode on techno-interface of BF-BOF route[J]. Iron and Steel,2008,43(12):83.)
[6] 邱剑,田乃媛. 典型流程区段炼铁炼钢界面的比较优势研究[J]. 北京科技大学学报,2005(6):740. (QIU Jian,TIAN Nai-yuan. Comparative advantage of ironmaking/steelmaking interface in typical process section[J]. Journal of University of Science and Technology Beijing,2005(6):740.)
[7] 周继程,郦秀萍,韩伟刚,等. 炼铁-炼钢界面模式与铁水罐多功能化技术[J]. 钢铁,2017,52(4):94. (ZHOU Ji-cheng,LI Xiu-ping,HAN Wei-gang,et al. Interface mode between BF and BOF and multifunctional hot metal ladle technology[J]. Iron and Steel,2017,52(4):94.)
[8] 谷宗喜,徐安军,贺东风,等. 多功能铁水包周转数计算模型[J]. 过程工程学报,2017,17(5):1035. (GU Zong-xi,XU An-jun,HE Dong-feng,et al. Calculation model for turnover number of multi-functional hot metal ladle[J]. The Chinese Journal of Process Engineering,2017,17(5):1035.)
[9] 王君,唐恩,范小刚,等. 铁水运输过程热损失模拟计算浅析[J]. 中国冶金,2015,25(4):12. (WANG Jun,TANG En,FAN Xiao-gang. Brief analysis of heat loss calculation in the hot metal transportation[J]. China Metallurgy,2015,25(4):12.)
[10] 廖哲灵,王净. 铁钢界面技术的效益优势比较研究[J]. 钢铁技术,2009(2):1. (LIAO Zhe-ling,WANG Jing. Comparative study on benefit advantages of ironmaking/steelmaking interface technology[J]. Iron and Steel Technology,2009(2):1.)
[11] 雷浩洪,吕凯辉. 炼铁-炼钢界面布局紧凑模式[J]. 中国冶金2021,31(4):64. (LEI Hao-hong,LÜ Kai-hui. Compact layout mode of ironmaking-steelmaking interface[J]. China Metallurgy,2021,31(4):64. )
[12] 韩伟刚,胡长庆,沙远洋. 铁钢界面铁水罐多功能化技术中的尾罐效应[J]. 钢铁,2021,56(4):122. (HAN Wei-gang,HU Chang-qing,SHA Yuan-yang. Tail ladle effect in hot metal ladle multi-functionalization technology in ironmaking-steelmaking interface[J]. Iron and Steel,2021,56(4):122. )
[13] 王新东. 以“绿色化、智能化、品牌化”为目标规划设计河钢唐钢新区[J]. 钢铁,2021,56(2):12. (WANG Xin-dong. Planning and design of HBIS Group Tangsteel new district with goal of "Green,Intelligent and Brand"[J]. Iron and Steel,2021,56(2):12. )
[14] 黄帮福,施哲,周晓雷,等. 基于铁水供求关系的鱼雷罐控制模型[J]. 昆明理工大学学报(自然科学版),2015,40(6):133. (HUANG Bang-fu,SHI Zhe,ZHOU Xiao-lei,et al. Control model of torpedo ladle based on hot metal supply and demand[J]. Journal of Kunming University of Science and Technology(Natural Science),2015,40(6):133.)
[15] 韩伟刚,郦秀萍,施一新,等. 基于排队论“一包到底”模式的在线铁水包数量[J]. 钢铁,2013,48(5):21. (HAN Wei-gang,LI Xiu-ping,SHI Yi-xin,et al. Online ladle quantity of “one-open-ladle-from-BF-to-BOF” route by using queuing theory[J]. Iron and Steel,2013,48(5):21.)
[16] 杨楚荣. “一罐到底”铁水运输工艺铁水罐配置的优化分析[C]//第十届中国钢铁年会暨第六届宝钢学术年会论文集. 上海:中国金属学会,2015:1221. (YANG Chu-rong. Quantity optimization and analysis of hot metal ladle for "common ladle system" hot metal transportation[C]//Papers of the 10th China Iron and Steel Annual Conference and the 6th Baogang Steel Academic Annual Conference. Shanghai:The Chinese Society for Metals,2015:1221.)
[17] 谷宗喜,徐安军,贺东风,等. 基于有限容量排队论的铁水包个数计算模型[J]. 重庆大学学报,2017,40(8):70. (GU Zong-xi,XU An-jun,HE Dong-feng,et al. Calculation model of ladle number based on finite capacity queuing theory[J]. Journal of Chongqing University,2017,40(8):70.)
[18] MENG Hua,WANG Hua,WANG Jian-jun,et al. Logistics simulation of BF-BOF region based on witness[J]. Advanced Materials Research,2012,433-440:2451.
[19] 谷宗喜. 高炉-转炉区段“界面技术”优化及仿真研究[D]. 北京: 北京科技大学,2018. (GU Zong-xi. Research on Optimization and Simulation of "Interface Technology" in BF-BOF Section[D]. Beijing:University of Science and Technology Beijing,2018.)
[20] 韩伟刚,胡长庆,郦秀萍,等. 炼铁-炼钢区段界面动态运行过程建模和仿真[J]. 中国冶金,2019,29(7):17. (HAN Wei-gang,HU Chang-qing,LI Xiu-ping,et al. Modeling and simulation of dynamic operation process of ironmaking-steelmaking interface[J]. China Metallurgy,2019,29(7):17.)
[21] 卢绍文,罗小川. “起重机+过跨车”铁水物流多场景仿真[J]. 系统仿真学报,2017,29(10):2549. (LU Shao-wen,LUO Xiao-chuan. Design of multi-scenairo simulation of molten iron logistics system with cranes and cross-train AGVs[J]. Journal of System Simulation,2017,29(10):2549.)
[22] 杨小燕,崔炳谋. 钢铁企业铁水运输调度优化与仿真[J]. 计算机应用,2013,33(10):2977. (YANG Xiao-yan,CUI Bing-mou. Molten iron transportation scheduling optimization and simulation of iron and steel enterprises[J]. Journal of Computer Applications,2013,33(10):2977.) |
| [1] |
YANG Chun-zheng. Practice and exploration of clean steel production with high efficiency and low cost[J]. Iron and Steel, 2021, 56(8): 20-25. |
| [2] |
HAN Wei-gang, HU Chang-qing, SHA Yuan-yang. Tail ladle effect in hot metal ladle multi-functionalization technology in ironmaking-steelmaking interface[J]. Iron and Steel, 2021, 56(4): 122-129. |
| [3] |
HAN Wei-gang, HU Chang-qing, SUN Yu-han, LU Yi-fan, MA Ju-an. Fluctuation characteristics of time parameter of ironmaking-steelmaking interface in steel manufacturing process[J]. Iron and Steel, 2021, 56(1): 120-126. |
| [4] |
WANG Sen-hui1,LI Hai-feng1,2,3,ZHANG Yong-jie1,ZOU Zong-shu1,2. Modeling and analysis of temperature drop prediction on techno-interface of BF-BOF route[J]. JOURNAL OF IRON AND STEEL RESEARCH , 2019, 31(11): 947-954. |
| [5] |
SHI Xin-yue,HAN Wei-gang,LI Xiu-ping,ZHANG Chun-xia,WU Chong-yuan,WEI Zhi-jun. “One Ladle Technology” operation practice analysis in Shougang Jingtang[J]. Iron and Steel, 2018, 53(2): 97-102. |
| [6] |
HAN Wei-gang,LI Xiu-ping,LIU Jian-hua,ZHANG Chun-xia,ZHOU Ji-cheng,SHI Xin-yue. Temperature drop of hot metal during BF tapping in Shougang Jingtang[J]. Iron and Steel, 2017, 52(6): 13-17. |
|
|
|
|
2021, Vol. 56 
