Transactions of Materials and Heat Treatment

Title：Research on permissive rolling range of strip steel product for hot continuous rolling based on rolling schedule optimization

Authors： Hou Jie Wang Tao Yang Xia Huang Qingxue

Unit： Taiyuan University of Science and Technology Coordinative Innovation Center of Taiyuan Heavy Machinery Equipment Taiyuan University of Technology

KeyWords： hot continuous rolling permissive rolling range constraint model schedule optimization strip steel

ClassificationCode：TG335.5

year,vol(issue):pagenumber：2018,43(2):0-0

Abstract：

Base on the constraint conditions of rolling temperature, rolling force, rolling torque and motor power, a constraint model of the smallest permissive rolling thickness for hot continuous rolling was established. Based on the limiting condition of optimal shape and aiming at the optimal object of relative equal load, a model of optimizing rolling schedule was established. Through the calculation and comparison, it is found that not only the optimized rolling schedule could guarantee a good shape of plate, but also the relative equal load distribution could fully play the ability of rolling mill and motor so as to calculate the minimum rolling thickness more accurately. According to this method, the simulation calculation program for permissive rolling range of products was developed under different widths and thicknesses. Therefore, this program has a high accuracy by comparison, and it could accurately reflect the rule of permissive rolling range of different steels. For a rolling line, when the product is wide, the minimum rolling thickness is mainly limited by the rolling force, rolling torque and other constraints. However, when the rolled workpiece is narrow, the rolling mill force parameter is rich, and the minimum rolling thickness is mainly limited to the finish rolling temperature.

Funds：

国家自然科学基金资助项目（51504157）；山西省青年基金面上资助项目（201701D221143）；山西省高等学校科技创新资助项目（2017132）

作者简介：侯洁（1988-），女，硕士，工程师 E-mail：houjie@yeah.net 通讯作者：王涛（1985-），男，博士，讲师 E-mail:tyutwt@163.com

Reference：

［1］胡锡增. 冷轧板材和带材最小可轧厚度的确定及最佳工作辊径的选择
［J］. 钢铁, 1982，17(4):39-44.

Hu X Z. The determination of minimum thickness and selection of optimal working roll diameter for cold-rolled strips
［J］．Iron and Steel, 1982，17(4):39-44.

［2］李小玉, 孙铁铠, 夏代润. 小型20辊轧机最小可轧厚度的实验研究
［J］. 钢铁研究学报, 1985，5(2):17-23.

Li X Y, Sun T K, Xia D R. Experimental study on the minimum roll able thickness in small-sized 20-high rolling mill
［J］. Journal of Iron and Steel Research, 1985，5(2):17-23.

［3］吴首民.极薄带钢轧制过程中最小可轧厚度的研究
［J］.中国冶金,2007,17(3):10-12.

Wu S M. Research of smallest permissive-rolling thickness during strip rolling
［J］. China Metallurgy, 2007,17(3):10-12.

［4］汤德林, 刘相华, 李翔宇. 同步轧制最小可轧厚度的实验研究
［J］. 热加工工艺, 2015，44(15):32-34.

Tang D L, Liu X H，Li X Y. Experimental research of permissive thickness in symmetrical rolling
［J］. Hot Working Technology, 2015，44(15):32-34.

［5］李翔宇. 极薄带材轧制及最小可轧厚度研究
［D］. 沈阳：东北大学, 2012.

Li X Y. Research on Extremely Thin Strip Rolling and Minimum Permissible Thickness
［D］. Shenyang: Northeastern University, 2012.

［6］刘相华, 宋孟, 孙祥坤,等. 极薄带轧制研究与应用进展
［J］. 机械工程学报, 2017, 53(10):1-9.

Liu X H, Song M, Sun X K, et al. Advances in research and application of foil rolling
［J］. Journal of Mechanical Engineering, 2017, 53(10):1-9.

［7］季青, 王守华. 考虑生产率时轧件最小可轧厚度的研究
［J］. 冶金设备管理与维修, 2004, 22(1):40-41.

Ji Q, Wang S H, Research on minimum rolling thickness of workpiece under consideration of productivity
［J］. Metallurgical Equipment Management and Maintenance, 2004, 22(1):40-41.

［8］李海军，时立军，王国栋.带钢热连轧机组温度模型及其自学习方法
［J］.东北大学学报,2009,30(5):369-372.

Li H J, Shi L J, Wang G D. Temperature model of hot strip finishing mills in tandem and its self-learning strategy
［J］. Journal of Northeastern University,2009,30(5):369-372.

［9］吕长宝. 热连轧带钢的温度模型与模拟应用
［J］. 轧钢, 2008, 25(6):15-18.

Lyu C B. Temperature model and its application in hot strip rolling
［J］. Steel Rolling, 2008, 25(6):15-18.

［10］刘艳, 孙一康, 管克智,等. 武钢1700 mm带钢热连轧精轧机组温降模型研究
［J］. 钢铁, 2004, 39(3):34-37.

Liu Y, Sun Y K, Guan K Z, et al. On temperature model for finishing stands in hot strip mill of Wuhan Iron and Steel Co.
［J］.Iron and Steel, 2004, 39(3):34-37.

［11］孙一康.带钢热连轧的模型与控制
［M］.北京:冶金工业出版社,2007.

Sun Y K. Model and Control of Hot Strip Mill
［M］. Beijing: Metallurgical Industry Press ,2007.

［12］朱宇,王涛.带钢热连轧轧制力计算研究
［J］. 机械设计与制造工程, 2013, 42(6):71-73.

Zhu Y, Wang T. The rolling force design in the hot rolling belt steel process
［J］. Machine Design and Manufacturing Engineering, 2013, 42(6):71-73.

［13］周纪华,管克智.金属塑性变形阻力
［M］.北京:机械工业出版社,1989.

Zhou J H, Guan K Z. Plastic Deformation Resistance of Metal
［M］.Beijing: China Machine Press,1989.

［14］黄守汉.塑性变形与轧制原理
［M］.北京:冶金工业出版社,1991.

Huang S H. Plastic Deformation and Rolling Principle
［M］. Beijing: Metallurgical Industry Press ,1989.

［15］Qi X D, Wang T, Xiao H. Optimization of pass schedule in hot strip rolling
［J］. Journal of Iron & Steel Research, 2012, 19(8):25-28.

［16］Wang J C, Chen C Z. On the optimization of a rolling force model for a hot strip finishing line
［J］. ISA Transaction, 2007, 46 (4):527-531.

［17］张进之，段春华，任璐，等. 板带轧制板形最佳规程的设定计算及应用
［J］.治金设备,2009,(6):15-21.

Zhang J Z, Duan C H, Ren L, et al. Shape optimal schedule setting calculation and application for sheet strip rolling
［J］. Metallurgical Equipment, 2009,(6):15-21.

［18］丁敬国,曾庆亮,胡贤磊,等.中厚板规程负荷分配中轧辊凸度协调分配方法
［J］.钢铁, 2009, 44(6):48-50.

Ding J G, Zeng Q L, Hu X L, et al. Coordination distribution method of roll crown to medium plate rolling schedule
［J］. Iron and Steel, 2009, 44(6):48-50.

［19］崔占利, 徐筱芗, 宋仁伯,等. 1780 mm热连轧板形控制系统的研究和优化
［J］. 河南冶金, 2011, 19(2):13-15.

Cui Z L, Xu X X, Song R B, et al. Research and optimization of plate shape control system in 1780 mm hot rolling line
［J］. Henan Metallurgy, 2011, 19(2):13-15.

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