基于单片机的压力/液位控制系统的设计研究
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摘要
本文介绍了国内外过程控制系统研究的发展过程、进展状况以及提高自动化程度的若干新技术;研究了过程控制实验装置TKGK—1的内在结构、控制对象以及主要特点;选取过程控制中的典型参数液位/压力为控制对象,设计了以PC机为上位机、以89C51单片机为下位机,并辅之以传感器、变频器以及相关接口部件的二级集散控制系统;着重介绍了基于TLC2543单片机的数据采集与处理系统和基于RS—232C通信标准的数据通信系统程序模块的设计思路、工作过程;介绍了提高系统抗干扰能力的看门狗电路。
基于单片机的TKGK—1过程控制系统的硬件和软件都采用模块化设计,硬件模块便于生产和维护;软件模块便于修改和升级。文中的数据采集与处理程序、上位机与下位机之间的通信程序都使用执行效率较高的汇编语言来完成,上位机的人机交互界面与数据输出程序采用高级语言VB来开发。
通过本文的研究,总结出了基于单片机过程控制系统的优势:体积小,实际应用系统简单实用,成本低,效益好;具有较高的性能价格比;系统不易受到干扰,可靠性高。本文为基于单片机的过程控制系统应用到实际生产过程做了有益的尝试,为提高我国过程控制自动化水平提供了有参考价值的设计思路。
This paper introduces the development of process control system, the nowadays situation and several new techniques, which are good for the improvement of automatization, in both China and other countries.
This paper has done many research, including: the immanent structure, controlling objects and the main features of TKGK—1 Process Control System; choosing the typical parameter—hydraulic position / pressure as the main object, we have designed a Distributed Control System, which is composed by PC, called epigyny computer, AT89C51, called hypogyny single chip, and other assistant equipments, such as sensor, transducer and related interface components. Putting the emphasis on the introduction of data collecting and disposing system, which is based on the single chip TLC2543, and the data traffic system, which is based on the communication standard RS—232C. The introduction contains the designing idea and working process of the formality module above. Introducing the Watch Dog circuit which is used to improve the anti—jamming ability of the system.
The hardware and software of the TKGK—1 Process Control System, which is based on the single chip, both use the modularize design. The hardware module is easy to produce and maintenance; the software module is easy to amend and upgrade. The data collecting and disposing formality and the communication formality, which is used between epigyny computer and hypogyny single chip, are both use the assemble language that has the high efficiency. The alternative interface of epigyny between human and computer, the formality which is used for exporting data, both use the high—class language VB.
According to the research of this paper, we can give a summarize of the advantages of the Process Control System which is based on the single chip: small; the application system is simple and practical; lower cost, good benefit; has the upper capability price ratio; has better anti—jamming ability and higher dependability. This paper is a availability attempt for putting the Process Control System which is based on single chip into practical manufacture. It also provides valuable design idea that can be used to improve the national process control automatization level.
基于单片机的TKGK—1过程控制系统的硬件和软件都采用模块化设计,硬件模块便于生产和维护;软件模块便于修改和升级。文中的数据采集与处理程序、上位机与下位机之间的通信程序都使用执行效率较高的汇编语言来完成,上位机的人机交互界面与数据输出程序采用高级语言VB来开发。
通过本文的研究,总结出了基于单片机过程控制系统的优势:体积小,实际应用系统简单实用,成本低,效益好;具有较高的性能价格比;系统不易受到干扰,可靠性高。本文为基于单片机的过程控制系统应用到实际生产过程做了有益的尝试,为提高我国过程控制自动化水平提供了有参考价值的设计思路。
This paper introduces the development of process control system, the nowadays situation and several new techniques, which are good for the improvement of automatization, in both China and other countries.
This paper has done many research, including: the immanent structure, controlling objects and the main features of TKGK—1 Process Control System; choosing the typical parameter—hydraulic position / pressure as the main object, we have designed a Distributed Control System, which is composed by PC, called epigyny computer, AT89C51, called hypogyny single chip, and other assistant equipments, such as sensor, transducer and related interface components. Putting the emphasis on the introduction of data collecting and disposing system, which is based on the single chip TLC2543, and the data traffic system, which is based on the communication standard RS—232C. The introduction contains the designing idea and working process of the formality module above. Introducing the Watch Dog circuit which is used to improve the anti—jamming ability of the system.
The hardware and software of the TKGK—1 Process Control System, which is based on the single chip, both use the modularize design. The hardware module is easy to produce and maintenance; the software module is easy to amend and upgrade. The data collecting and disposing formality and the communication formality, which is used between epigyny computer and hypogyny single chip, are both use the assemble language that has the high efficiency. The alternative interface of epigyny between human and computer, the formality which is used for exporting data, both use the high—class language VB.
According to the research of this paper, we can give a summarize of the advantages of the Process Control System which is based on the single chip: small; the application system is simple and practical; lower cost, good benefit; has the upper capability price ratio; has better anti—jamming ability and higher dependability. This paper is a availability attempt for putting the Process Control System which is based on single chip into practical manufacture. It also provides valuable design idea that can be used to improve the national process control automatization level.
引文
[1] 金以慧.过程控制[J].北京:清华大学出版社,1993,19~21
[2] Shuakla N V, Deshpande P B. Enhancing the robustness of internal-basedno nlinear pH control. Chemical Engineering Science,48,5,1993,913~920
[3] Gustafsson T K,Waller K V. Nonlinear and adaptive control of pH. Industrial & EngineeringChemistry Research,31,12,1992,2681~2693
[4] 房小翠等.单片微型计算机与机电接口技术[M].国防工业出版社,2002:3~4
[5] 王桂花.过程控制中流量模糊控制系统的研究[D].合肥工业大学研究生部,2006:6~8
[6] 季绍陵,王国新.过程控制与TKGK—1实验装置[J].常熟高专学报,2004,18(2):109~112
[7] 刘照红,王留芳,吴娟.扩散硅压力传感器在水力模型实验装置液位测控中的应用[J].郑州轻工业学院学报,2004,19(4):77~78
[8] 孙钊,刘继勇,刘星.扩散硅液位变送器测量系统的可靠性设计[J].西安工业学院学报,2005,25(3):232~234
[9] 孙育才,王荣兴,孙华芳.ATMEL新型AT89S52系列单片机及其应用[M].清华大学出版社,2005:1~5
[10] 万君福等.单片机原理系统设计与开发应用[M].中国科学技术出版社,1995:322~325
[11] TKGK-1过程控制实验装置组成和各部分使用说明.杭州天科技术公司天煌教学仪器厂,2003:1~17
[12] 朱武等.多功能多参数的过程控制实验装置[J].中国教育与发展,2006,85(6):65~67
[13] 逢启涛,黄伟玲,王忠蜂,冯羽生.基于模糊控制技术的单片机恒压供水系统[J].自动化技术与应用,2006,25(5),77~78
[14] 张立科.单片机典型模块设计实例导航[M].人民邮电出版社,2002:142~149,366~368
[15] 梁汉文,韦宁.TLC2543多通道串行A/D转换器及其C51语言单片机应用程序[J].广西大学梧州分校学报,2003,13(3):54~57
[16] 程继红.TLC2543在传感器实验台测试系统中的应用[J].南京师范大学学报,2003,3(1):65~69
[17] TLC2543模数转换器数据手册及应用笔记.武汉力源电力股份有限公司,1999
[18] NEW RELEASE DATA BOOK (Volume V) .MAXIM. 1996:2—61~2—72
[19] 李映颖,王海军,孟详谦.串行A/D转换器TLC2543与51系列单片机的接口设计[J].仪表技术,2004,1:22~23
[20] 王力,赵庆玲.基于AT89S51和USB接口的实时数据采集系统设计[J].电子工程师,2006,32(11):72~74
[21] 杨叔子,杨克冲等.机械工程控制基础[M].华中科技大学出版社,2001:191~198
[22] 王永初.PID调节的现代观[J].自动化仪表,1998,19(5):1~3
[23] 王蕾,宋文忠.PID控制[J].自动化仪表,2004,25(4),1~5
[24] 陈建洪.PID控制程序在恒压水系统中的应用[J].龙沿师专学报,2004,22 (3):24~26
[25] 张峰.PID控制技术及其在玻璃工业中的应用[J].山西建材,2000:33~35
[26] 赵旺达,鲁五一,徐志胜,刘子建.PID控制器及其智能化方法探讨[J].化工自动化及仪表,1999,26(6),45~48
[27] 付军.变速积分PID算法及在单片机流量比例控制系统中的应用[J].武汉水利电力大学学报合大学学报,1994,27(2),204~207
[28] A Y Allidina et al. Generalized Self tuning Controller with Pole Assignment [J]. IEE PROC, 1980,127(1)
[29] LEE C C. Fuzzy Logic in Control Systems [J]. Fuzzy Logic Controller IEEE Trans, on SMC, 1990, 20(2)
[30] 谈宏华,陈康,涂坦,肖仁伟.基于AT89C51的数据采集系统设计[J].机电一体化,2005,6:55~57
[31] 施吉方.单片机数据采集器的设计[J].电测与仪表,1998(1):26~28
[32] 朱世鸿.微机系统和接口应用技术[M].清华大学出版社,2006,398~403
[33] 何小阳.计算机监控原理及技术[M].重庆大学出版社,2003:84~85
[34] 陈德池.微处理器与现场总线技术[M].中南大学出版社,2003:95~98
[35] 吴炳胜等.80C51单片机原理与应用技术[M].冶金工业出版社,2006,89~106
[36] 何宏,龚威,田志宏.单片机原理与接口技术[M].国防工业出版社,2006,178~190
[37] 范逸之.Visual Basic与RS—232串行通信控制[M].中国青年出版社,2002:1~3,107~14
[38] 张长森.矿用交换机调度台RS—232接口电路设计[J].煤矿机械,2004,11:13~15
[39] 赵仕元.基于PTR2000的无线数据传输系统[J].机电产品开发与创新, 2004,17(4):69~71
[40] 戴明.浅谈单片机对Modem的控制[J].无锡商业职业技术学院学报,2006,6(3):29~31
[41] 陈小忠,黄宁,赵小侠.单片机接口技术实用子程序[M].人民邮电出版社,2005,58~65
[42] 张飞乔.用Visual Basic开发微机通信程序[J].湖南电力,2000,20(6):53~56
[43] 张红兵.VB6.0环境下利用Mscomm控件实现串行通信[J].微计算机信息,1999,18(12):66~68
[44] 陈涛.污水处理集散控制系统中模拟量的测控[D].合肥工业大学研究生部,2005,29~31
[45] 冯力,郝迎吉,张斌.基于VB数据库的单片机主从式串口通讯[J].现代电子技术,2000,11:63~65
[46] 崔村燕.污水处理过程的计算机监控研究[D].合肥工业大学研究生部,2002:36~37
[47] 林慕新.Visual Basic6.0实例教程[M].电子工业出版社,1999
[48] 王红庆,郭英杰,李春明.X25045芯片及其应用[J].计算机应用天地,2003,12:64~65
[49] 凌云,何丽平.MCS—51单片机中看门狗技术的应用[J].湖南冶金职业技术学院学报,2004,4(4):303~305
[50] 史延龄,邹来智,王正兰.X25045与单片机的接口及编程[J].仪器仪表用户,2002,9:42~45
[51] 庞伟,田东方,冯英霞.基于C51语言的看门狗芯片X25045的控制方法[J].长春工程学院学报(自然科学版),2003,4(2):64~66
[52] 谢辉.基于X25045的新型看门狗电路[J].今日电子,2006,2:80~81
[53] 刘辉,周志英.X25045芯片在微机测控系统中的应用[J].电气时代,2002,8:50~51
[54] 何立民.单片机应用文集[M].北京:航天航空大学出版社,1991
[55] 朱武.过程装备控制技术实验指导书.合肥工业大学机械与汽车工程学院,2003:2~9
[2] Shuakla N V, Deshpande P B. Enhancing the robustness of internal-basedno nlinear pH control. Chemical Engineering Science,48,5,1993,913~920
[3] Gustafsson T K,Waller K V. Nonlinear and adaptive control of pH. Industrial & EngineeringChemistry Research,31,12,1992,2681~2693
[4] 房小翠等.单片微型计算机与机电接口技术[M].国防工业出版社,2002:3~4
[5] 王桂花.过程控制中流量模糊控制系统的研究[D].合肥工业大学研究生部,2006:6~8
[6] 季绍陵,王国新.过程控制与TKGK—1实验装置[J].常熟高专学报,2004,18(2):109~112
[7] 刘照红,王留芳,吴娟.扩散硅压力传感器在水力模型实验装置液位测控中的应用[J].郑州轻工业学院学报,2004,19(4):77~78
[8] 孙钊,刘继勇,刘星.扩散硅液位变送器测量系统的可靠性设计[J].西安工业学院学报,2005,25(3):232~234
[9] 孙育才,王荣兴,孙华芳.ATMEL新型AT89S52系列单片机及其应用[M].清华大学出版社,2005:1~5
[10] 万君福等.单片机原理系统设计与开发应用[M].中国科学技术出版社,1995:322~325
[11] TKGK-1过程控制实验装置组成和各部分使用说明.杭州天科技术公司天煌教学仪器厂,2003:1~17
[12] 朱武等.多功能多参数的过程控制实验装置[J].中国教育与发展,2006,85(6):65~67
[13] 逢启涛,黄伟玲,王忠蜂,冯羽生.基于模糊控制技术的单片机恒压供水系统[J].自动化技术与应用,2006,25(5),77~78
[14] 张立科.单片机典型模块设计实例导航[M].人民邮电出版社,2002:142~149,366~368
[15] 梁汉文,韦宁.TLC2543多通道串行A/D转换器及其C51语言单片机应用程序[J].广西大学梧州分校学报,2003,13(3):54~57
[16] 程继红.TLC2543在传感器实验台测试系统中的应用[J].南京师范大学学报,2003,3(1):65~69
[17] TLC2543模数转换器数据手册及应用笔记.武汉力源电力股份有限公司,1999
[18] NEW RELEASE DATA BOOK (Volume V) .MAXIM. 1996:2—61~2—72
[19] 李映颖,王海军,孟详谦.串行A/D转换器TLC2543与51系列单片机的接口设计[J].仪表技术,2004,1:22~23
[20] 王力,赵庆玲.基于AT89S51和USB接口的实时数据采集系统设计[J].电子工程师,2006,32(11):72~74
[21] 杨叔子,杨克冲等.机械工程控制基础[M].华中科技大学出版社,2001:191~198
[22] 王永初.PID调节的现代观[J].自动化仪表,1998,19(5):1~3
[23] 王蕾,宋文忠.PID控制[J].自动化仪表,2004,25(4),1~5
[24] 陈建洪.PID控制程序在恒压水系统中的应用[J].龙沿师专学报,2004,22 (3):24~26
[25] 张峰.PID控制技术及其在玻璃工业中的应用[J].山西建材,2000:33~35
[26] 赵旺达,鲁五一,徐志胜,刘子建.PID控制器及其智能化方法探讨[J].化工自动化及仪表,1999,26(6),45~48
[27] 付军.变速积分PID算法及在单片机流量比例控制系统中的应用[J].武汉水利电力大学学报合大学学报,1994,27(2),204~207
[28] A Y Allidina et al. Generalized Self tuning Controller with Pole Assignment [J]. IEE PROC, 1980,127(1)
[29] LEE C C. Fuzzy Logic in Control Systems [J]. Fuzzy Logic Controller IEEE Trans, on SMC, 1990, 20(2)
[30] 谈宏华,陈康,涂坦,肖仁伟.基于AT89C51的数据采集系统设计[J].机电一体化,2005,6:55~57
[31] 施吉方.单片机数据采集器的设计[J].电测与仪表,1998(1):26~28
[32] 朱世鸿.微机系统和接口应用技术[M].清华大学出版社,2006,398~403
[33] 何小阳.计算机监控原理及技术[M].重庆大学出版社,2003:84~85
[34] 陈德池.微处理器与现场总线技术[M].中南大学出版社,2003:95~98
[35] 吴炳胜等.80C51单片机原理与应用技术[M].冶金工业出版社,2006,89~106
[36] 何宏,龚威,田志宏.单片机原理与接口技术[M].国防工业出版社,2006,178~190
[37] 范逸之.Visual Basic与RS—232串行通信控制[M].中国青年出版社,2002:1~3,107~14
[38] 张长森.矿用交换机调度台RS—232接口电路设计[J].煤矿机械,2004,11:13~15
[39] 赵仕元.基于PTR2000的无线数据传输系统[J].机电产品开发与创新, 2004,17(4):69~71
[40] 戴明.浅谈单片机对Modem的控制[J].无锡商业职业技术学院学报,2006,6(3):29~31
[41] 陈小忠,黄宁,赵小侠.单片机接口技术实用子程序[M].人民邮电出版社,2005,58~65
[42] 张飞乔.用Visual Basic开发微机通信程序[J].湖南电力,2000,20(6):53~56
[43] 张红兵.VB6.0环境下利用Mscomm控件实现串行通信[J].微计算机信息,1999,18(12):66~68
[44] 陈涛.污水处理集散控制系统中模拟量的测控[D].合肥工业大学研究生部,2005,29~31
[45] 冯力,郝迎吉,张斌.基于VB数据库的单片机主从式串口通讯[J].现代电子技术,2000,11:63~65
[46] 崔村燕.污水处理过程的计算机监控研究[D].合肥工业大学研究生部,2002:36~37
[47] 林慕新.Visual Basic6.0实例教程[M].电子工业出版社,1999
[48] 王红庆,郭英杰,李春明.X25045芯片及其应用[J].计算机应用天地,2003,12:64~65
[49] 凌云,何丽平.MCS—51单片机中看门狗技术的应用[J].湖南冶金职业技术学院学报,2004,4(4):303~305
[50] 史延龄,邹来智,王正兰.X25045与单片机的接口及编程[J].仪器仪表用户,2002,9:42~45
[51] 庞伟,田东方,冯英霞.基于C51语言的看门狗芯片X25045的控制方法[J].长春工程学院学报(自然科学版),2003,4(2):64~66
[52] 谢辉.基于X25045的新型看门狗电路[J].今日电子,2006,2:80~81
[53] 刘辉,周志英.X25045芯片在微机测控系统中的应用[J].电气时代,2002,8:50~51
[54] 何立民.单片机应用文集[M].北京:航天航空大学出版社,1991
[55] 朱武.过程装备控制技术实验指导书.合肥工业大学机械与汽车工程学院,2003:2~9