连铸控制系统在穆巴拉克板坯生产线上的应用
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摘要
对连铸过程控制系统在伊朗穆巴拉克板坯连铸生产线中的应用进行了介绍。穆巴拉克连铸生产线的过程控制系统主要包括了连铸生产物料跟踪与制造命令执行和连铸生产工艺控制数学模型两个部分。连铸生产物料跟踪与制造命令执行系统的应用实现了连铸生产过程的数字化、透明化和无纸化,使得炼钢与轧制工序之间的生产信息流得以贯通,有效的提升了连铸生产的自动化和信息管理水平,降低了操作人员的工作量;连铸生产工艺控制数学模型的应用使得最终产品的质量得到了很大的提高,给企业带来了可观的经济效益。
The paper describes the application of continuous casting process control system in Mobrarakeh steel plant's continuous casting production line. The continuous casting process control system mainly include two parts. One is continuous casting production material trace and manufacture command execution subsystem. The other is production technology control mathematic model subsystem. Casting production material trace and manufacture command execution's application realize the continuous cast production digitization and transparent and paperless. It makes the information flow smooth between the steelmaking and steel rolling and increases the automation and information management level and decreases the operator's workload. Production technology control mathematic model greatly improve the product quality and gain the huge economic benefit for enterprise.
The paper describes the application of continuous casting process control system in Mobrarakeh steel plant's continuous casting production line. The continuous casting process control system mainly include two parts. One is continuous casting production material trace and manufacture command execution subsystem. The other is production technology control mathematic model subsystem. Casting production material trace and manufacture command execution's application realize the continuous cast production digitization and transparent and paperless. It makes the information flow smooth between the steelmaking and steel rolling and increases the automation and information management level and decreases the operator's workload. Production technology control mathematic model greatly improve the product quality and gain the huge economic benefit for enterprise.
引文
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[2]孙一康,王京.冶金过程自动化基础[M].北京:冶金工业出版社,2006:4.
[3]何冰,米进周,王旭英,等.连铸生产线智能化方向的初步探究[J].重型机械,2017(5):3.
[4]温恒,高朝波,米进周,等.攀钢西昌板坯连铸过程跟踪系统的实现与应用[J].重型机械,2013,312(S1):282.
[5]王兴兵,周晓敏,刘乐.连铸板坯切割长度优化系统的研究[J].机械工程与自动化,2007(5):4.
[6]龙勇.攀钢2#连铸机切割优化模型的设计与实现[J].控制工程,2003(5):143.
[7]孙立根,张家泉.大方坯连铸切割优化模型的研究[J].连铸,2008(3):5
[8]高朝波,米进周,王旭英,等.对智能连铸坯质量判定系统实施的研究[C]//《连铸》杂志编辑部、中国金属学会连铸分会. 2015连铸装备的技术创新和精细化生产技术交流会会议论文集.西安:中国金属学会,2015(6):238.
[9]柯磊,高仲,韩传基,等.连铸坯质量预测系统及应用[J].冶金自动化,2012(1):45.
[10]郭英敏.连铸坯质量在线判定系统的研究[J].冶金自动化,2015(S2):34.
[11]王水根.圆坯连铸凝固传热模型及二冷动态控制研究[D].重庆:重庆大学,2010:4.
[12]米进周,石晓梅,温恒.动态二冷水控制系统在圆坯连铸中的应用[J].重型机械,2014(1):18.
[13]杨跃标,祭程,罗森,等.连铸动态二冷控制模型的开发与应用[J].钢铁,2010(9):49.
[14]米进周,温恒,赵静等.攀钢板坯连铸动态轻压下系统的实现与应用[J].重型机械,2013,312(S1):63.
[15]马玉堂,杨拉道,张琦,等.板坯连铸动态轻压下辊缝调节的自适应功能[J].重型机械,2010(S1):46.
[16]刘启龙,刘国平,司晓明,等. S650MC高强钢连铸轻压下工艺优化[J].炼钢,2017(4):35.