110T铜转炉生产过程余热锅炉水位控制系统
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摘要
余热锅炉是一个多输入、多输出且相互关联的复杂控制对象,汽包水位是锅炉运行的主要指标。由于普遍存在容量较小,热源不稳定的情况,导致锅筒水位波动剧烈,传统三冲量控制规律的控制效果不好。本论文通过对某110T转炉余热锅炉的工艺过程和动态特性进行分析,提出了小型余热锅炉的改进三冲量控制方案,并进行硬件结构设计,组成控制系统对改进三冲量控制规律予以实施。运行结果表明本系统能够基本消除热源波动对水位的影响,同时提高了蒸汽产量和质量,改变了余热锅炉手动运行的现状,对降低人员劳动强度、节约生产成本、提高经济效益都具有重要意义。
在系统设计时,利用PLC功能较强、运行稳定的特点,构成由上位工控机和下位PLC组成的控制系统,通过以太网交换过程变量和控制参数的硬件结构。下位机选用美国通用电气公司的GE Fanuc90—30系列PLC上位机应用程序采用CETECT 5.4组态软件设计。论文概述了转炉生产的工艺过程,分析了锅筒水位的动态特性;着重论述了改进三冲量控制规律的推导及应用过程中的性能分析;设计了适合余热锅炉的并联FUZZY/模糊自适应PID控制算法;编制了控制策略的相应软件。应用结果表明,本论文提出的设计方法能有效地对余热锅炉水位及其他过程参数进行控制,具有广泛的应用前景。
Waste heat boiler is a multi-input and output system. The drum water level is the most important target in boiler's running. Because of the vary of heat resource, the water level in drum could not be controlled hrough the traditional three variable controlled way. In this thesis, dynamic characteristic of drum water level in the copper converter smelting process of 110 ton was discussed. Relationship between different disturbances was studied also. After the shortage analysis of traditional control scheme, a improved three variables control scheme had been presented. Additional, in this thesis had designed the firmware system to apply the control scheme, the running has showed that the control system could decrease the water level' flow, the steam' quality and quantity has increased at the same time. The application of this system had changed the waste heat boiler' running way, and increased the running efficient.
The control system' firmware is designed by using PLC and computer communicate through Ethernet to apply the improved three variables control. GE, FANUC 90-30 series programmer logic controller was chosen to realize control request, and CITECT software is used to supervise the procedure. To increase the robust ability, a Fuzzy/Self Adaptive Fuzzy PID controller is used. The running result proves that, the control system' design in this thesis is efficient in the waste heat boiler' control, and has a more optimistic foreground to use it extend.
在系统设计时,利用PLC功能较强、运行稳定的特点,构成由上位工控机和下位PLC组成的控制系统,通过以太网交换过程变量和控制参数的硬件结构。下位机选用美国通用电气公司的GE Fanuc90—30系列PLC上位机应用程序采用CETECT 5.4组态软件设计。论文概述了转炉生产的工艺过程,分析了锅筒水位的动态特性;着重论述了改进三冲量控制规律的推导及应用过程中的性能分析;设计了适合余热锅炉的并联FUZZY/模糊自适应PID控制算法;编制了控制策略的相应软件。应用结果表明,本论文提出的设计方法能有效地对余热锅炉水位及其他过程参数进行控制,具有广泛的应用前景。
Waste heat boiler is a multi-input and output system. The drum water level is the most important target in boiler's running. Because of the vary of heat resource, the water level in drum could not be controlled hrough the traditional three variable controlled way. In this thesis, dynamic characteristic of drum water level in the copper converter smelting process of 110 ton was discussed. Relationship between different disturbances was studied also. After the shortage analysis of traditional control scheme, a improved three variables control scheme had been presented. Additional, in this thesis had designed the firmware system to apply the control scheme, the running has showed that the control system could decrease the water level' flow, the steam' quality and quantity has increased at the same time. The application of this system had changed the waste heat boiler' running way, and increased the running efficient.
The control system' firmware is designed by using PLC and computer communicate through Ethernet to apply the improved three variables control. GE, FANUC 90-30 series programmer logic controller was chosen to realize control request, and CITECT software is used to supervise the procedure. To increase the robust ability, a Fuzzy/Self Adaptive Fuzzy PID controller is used. The running result proves that, the control system' design in this thesis is efficient in the waste heat boiler' control, and has a more optimistic foreground to use it extend.
引文
[1] 陈怀斌.余热利用与余热锅炉.应用能源技术,1997,8(12):20~21
[2] 夏明.有色冶炼用余热锅炉的自动控制.电子仪器仪表用户,1997,4(4):23~25
[3] 李英华.PLC在75t/h锅炉自动控制系统中的应用.冶金动力,2000,2(7):68~70
[4] 许庆斌.锅炉锅筒液位调节控制系统的选择.发电设备,1999,10(1):9~11
[5] 郭志波.PLC在75t/h锅炉汽包水位控制中的应用.仪器仪表标准化与计量,2002,3(3):5~7
[6] 何彤.余热锅炉工艺参数的检测控制及补偿.控制系统,2001,4(5):44~48
[7] 许韵.余热锅炉汽包水位检测误差分析及措施.有色设备,1999,2(2):18~20
[8] 吴麒.自动控制原理.北京:清华大学出版社,1990.121~163
[9] 金以慧.过程控制.北京:清华大学出版社,1998.163~195
[10] Kundu, K. M, Banevjee, D. Bhaduri, D. Theoretical Analysis On Flame Stabilization by a Bluff-Body. Combustion Science. and Technology 1977(17): 55~61
[11] 张蕴端.自动化及仪表.上海:华东化工学院出版社,1999:289~290
[12] 赵景波,周祥龙.预测函数控制在工业锅炉燃烧系统上的应用.工业仪表与自动化装置,2003(3):24~25
[13] 程昱宁.基于模糊Smith串级复合控制的温室加热系统研究.上海大学学报,2000(增刊):143~147
[14] 陶永华,尹怡欣等.新型PID控制及其应用.北京:机械工业出版社,2000.173~201
[15] 倪忠远,李秀志等.自整定PID-FUZZY控制器在炉温控制中的应用.自动化与仪器仪表,1998(5):4~7
[16] Elena Grassi and Kostas Tsakalis. PID Control Turning by
Frequency Loop-Shapeing: Application to Diffusion Furance Temprature Control. IEEE Trans. On Control Systems Tech. 2000, 8 (5): 165~169
[17] Li zhen and Longya Xu. Fuzzy leafing Enhanced Speed Control of an Indirect Field-Oriented Inductiong Machine Drive. IEEE Trans. On Control Systems Tech. 2000, 8 (5): 270~278
[18] 谭冠政,陈勇旗.基于DSP和模糊PD控制的职能人工腿位置伺服控制系统.中南工业大学学报,2001,32(4):35~37
[19] 王学慧,田成方.微机模糊控制理论及其应用.北京:电子工业出版社,1998.99~137
[20] 韩玉涛,张奕黄.基于DSP的开关磁组电动机模糊控制系统.制造业自动化,2001(3):33~38
[21] 涂承宇,涂承媛等.模糊控制理论与实践.北京:地震出版社,1998.22~68
[22] 黄宋魏,黎成,张勇.工业锅炉汽包液位模糊串级控制.云南冶金,2002,29(6):45~47
[23] 薛定宇.反馈控制系统设计与分析——MATLAB语言应用.北京:清华大学出版社,2000.56~82.
[24] 钟肇新,王灏.可编程控制器入门教程.广州:华南理工大学出版社,1099 23~46
[25] Kickert, W. J. M. andMatndani, E. H. Analysis of a fuzzy logic controller, Fuzzy Sets and Systems, 1998(1): 29~44
[26] K J Astrom, C C Hang, P Persson. Towards Intelligent PID Control. Automatic, 1998, 28(1): 251~261
[27] Spyros Tzafestas, Nikolaos P Papanikolopoulos. Incremental Fuzzy Expert PID Control IEEE Transactions on Industrial Electronics. 1990, 37(5): 365~371
[28] 孙伟.三冲量锅筒水位自适应神经元控制算法.中国矿业大学学报,2002(9):44~45
[29] Tong, R. M. Some properties of fuzzy feedback systems. IEEE Trans. Syst. Man Cybern, 1998 (10): 327~330
[30] Barto A G, Sutton R S. Andarson C W. Neuron like adaptive elements that can Solve difficult learning control problems. IEEE Trans, On Systems, Man and Cybernetics, 1999, SMC-13(5): 834~846
[31] Kickert, W. J. M. and Matndani, E. H. Analysis of a fuzzy logic controller. Fuzzy Sets and Systems, 1998(1): 29~32
[32] Versapro Programming Software User's Guide. GE Fanuc Automation. 2000. 10~44
[33] 陈沪村.计算机群控余热锅炉系统.新技术新工艺.1999,2(2):3~4
[34] 王嵩岐.废热锅炉两种非正常运行的原因分析.齐鲁石油化工,2001(1):44~46
[35] 刘吉臻.协调控制与给水全程控制,北京:水利电力出版社,1996
[36] 周洪明.转炉余热锅炉汽包水位的控制.冶金能源.2003,18(3):49~52
[37] S30指令系统.GE公司,1999.15~96
[38] 王兆安,黄俊.电力电子技术.北京:机械工业出版社,1999.63~75
[39] 鲁学农,张朝阳.锅炉汽包水位保护逻辑优化.华北电力技术,2003(6):99~103
[40] 王智.锅炉汽包水位的自动控制.化工科技市场,2003(8):46~50
[41] 胡寿松.自动控制原理(第3版).北京:国防工业出版社,2000.235~260
[42] 戴忠达.自动控制理论基础.北京:清华大学出版社,2001.115~119
[43] 陈曦,姚普光.工业控制软件的面向对象开发技术.河北工业大学学报,1998,27(2):107~113
[44] 郑震宇,周立等.Windows平台上过程监控软件的设计.工业控制计算机,1999,12(6):42~54
[45] 刘树江.用N-90集散控制系统实现锅炉水位控制.辽宁工程技术大学学报,1999(8):69~72
[2] 夏明.有色冶炼用余热锅炉的自动控制.电子仪器仪表用户,1997,4(4):23~25
[3] 李英华.PLC在75t/h锅炉自动控制系统中的应用.冶金动力,2000,2(7):68~70
[4] 许庆斌.锅炉锅筒液位调节控制系统的选择.发电设备,1999,10(1):9~11
[5] 郭志波.PLC在75t/h锅炉汽包水位控制中的应用.仪器仪表标准化与计量,2002,3(3):5~7
[6] 何彤.余热锅炉工艺参数的检测控制及补偿.控制系统,2001,4(5):44~48
[7] 许韵.余热锅炉汽包水位检测误差分析及措施.有色设备,1999,2(2):18~20
[8] 吴麒.自动控制原理.北京:清华大学出版社,1990.121~163
[9] 金以慧.过程控制.北京:清华大学出版社,1998.163~195
[10] Kundu, K. M, Banevjee, D. Bhaduri, D. Theoretical Analysis On Flame Stabilization by a Bluff-Body. Combustion Science. and Technology 1977(17): 55~61
[11] 张蕴端.自动化及仪表.上海:华东化工学院出版社,1999:289~290
[12] 赵景波,周祥龙.预测函数控制在工业锅炉燃烧系统上的应用.工业仪表与自动化装置,2003(3):24~25
[13] 程昱宁.基于模糊Smith串级复合控制的温室加热系统研究.上海大学学报,2000(增刊):143~147
[14] 陶永华,尹怡欣等.新型PID控制及其应用.北京:机械工业出版社,2000.173~201
[15] 倪忠远,李秀志等.自整定PID-FUZZY控制器在炉温控制中的应用.自动化与仪器仪表,1998(5):4~7
[16] Elena Grassi and Kostas Tsakalis. PID Control Turning by
Frequency Loop-Shapeing: Application to Diffusion Furance Temprature Control. IEEE Trans. On Control Systems Tech. 2000, 8 (5): 165~169
[17] Li zhen and Longya Xu. Fuzzy leafing Enhanced Speed Control of an Indirect Field-Oriented Inductiong Machine Drive. IEEE Trans. On Control Systems Tech. 2000, 8 (5): 270~278
[18] 谭冠政,陈勇旗.基于DSP和模糊PD控制的职能人工腿位置伺服控制系统.中南工业大学学报,2001,32(4):35~37
[19] 王学慧,田成方.微机模糊控制理论及其应用.北京:电子工业出版社,1998.99~137
[20] 韩玉涛,张奕黄.基于DSP的开关磁组电动机模糊控制系统.制造业自动化,2001(3):33~38
[21] 涂承宇,涂承媛等.模糊控制理论与实践.北京:地震出版社,1998.22~68
[22] 黄宋魏,黎成,张勇.工业锅炉汽包液位模糊串级控制.云南冶金,2002,29(6):45~47
[23] 薛定宇.反馈控制系统设计与分析——MATLAB语言应用.北京:清华大学出版社,2000.56~82.
[24] 钟肇新,王灏.可编程控制器入门教程.广州:华南理工大学出版社,1099 23~46
[25] Kickert, W. J. M. andMatndani, E. H. Analysis of a fuzzy logic controller, Fuzzy Sets and Systems, 1998(1): 29~44
[26] K J Astrom, C C Hang, P Persson. Towards Intelligent PID Control. Automatic, 1998, 28(1): 251~261
[27] Spyros Tzafestas, Nikolaos P Papanikolopoulos. Incremental Fuzzy Expert PID Control IEEE Transactions on Industrial Electronics. 1990, 37(5): 365~371
[28] 孙伟.三冲量锅筒水位自适应神经元控制算法.中国矿业大学学报,2002(9):44~45
[29] Tong, R. M. Some properties of fuzzy feedback systems. IEEE Trans. Syst. Man Cybern, 1998 (10): 327~330
[30] Barto A G, Sutton R S. Andarson C W. Neuron like adaptive elements that can Solve difficult learning control problems. IEEE Trans, On Systems, Man and Cybernetics, 1999, SMC-13(5): 834~846
[31] Kickert, W. J. M. and Matndani, E. H. Analysis of a fuzzy logic controller. Fuzzy Sets and Systems, 1998(1): 29~32
[32] Versapro Programming Software User's Guide. GE Fanuc Automation. 2000. 10~44
[33] 陈沪村.计算机群控余热锅炉系统.新技术新工艺.1999,2(2):3~4
[34] 王嵩岐.废热锅炉两种非正常运行的原因分析.齐鲁石油化工,2001(1):44~46
[35] 刘吉臻.协调控制与给水全程控制,北京:水利电力出版社,1996
[36] 周洪明.转炉余热锅炉汽包水位的控制.冶金能源.2003,18(3):49~52
[37] S30指令系统.GE公司,1999.15~96
[38] 王兆安,黄俊.电力电子技术.北京:机械工业出版社,1999.63~75
[39] 鲁学农,张朝阳.锅炉汽包水位保护逻辑优化.华北电力技术,2003(6):99~103
[40] 王智.锅炉汽包水位的自动控制.化工科技市场,2003(8):46~50
[41] 胡寿松.自动控制原理(第3版).北京:国防工业出版社,2000.235~260
[42] 戴忠达.自动控制理论基础.北京:清华大学出版社,2001.115~119
[43] 陈曦,姚普光.工业控制软件的面向对象开发技术.河北工业大学学报,1998,27(2):107~113
[44] 郑震宇,周立等.Windows平台上过程监控软件的设计.工业控制计算机,1999,12(6):42~54
[45] 刘树江.用N-90集散控制系统实现锅炉水位控制.辽宁工程技术大学学报,1999(8):69~72
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