基于松散度检测的风阀参数调控系统
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摘要
跳汰选煤是煤炭行业的重要选煤方法。电磁风阀作为跳汰机的关键设备,其工作可靠性直接影响到跳汰机的整机运行,其自动化控制是跳汰机整机自动化的重要组成部分。由于跳汰过程极为复杂,而且各影响因素之间互相牵连,在生产操作过程中,跳汰司机需要根据入料原料、入料量、工作风压以及床层厚度等条件的变化,凭借经验,不断的调整风阀参数。人为主观因素参与到控制过程,这对于跳汰过程来说,应用一般的控制方法会存在一定的困难。因此,风阀的自动控制需要一种智能化的控制方法,需要将专家知识和智能行为融入到控制系统中,从而得到更为有效的控制效果。
本论文提出了一种跳汰机风阀的专家系统自动调控方法。专家系统是基于知识的智能推理系统,集人工智能和领域知识于一体,涉及到知识获取、知识库、推理机制以及智能人—机交互界面的研究,已在众多领域获得广泛应用,大大提高了工作效率和工作质量,促进了人类智能和机器智能的相互补充和相互渗透。本专家系统的专家知识来源于选煤专家经验及跳汰机操作人员
太原理工大学硕士研究生学位论文
长期积累的经验、现场数据分析和实验总结等。专家系统会根据
实时采集反馈回的现场床层的密度和浮标等信号,基于获取的专
家知识,调用推理规则,进行智能推理,实现对风阀参数适当的
修改,从而得到合理的风阀参数。
本专家系统以WindowS 2000为开发平台,以面向对象的编程
工具VISual Basic 6.0为开发工具,实现了整个专家系统的软件
编程。使用面向对象的数据库编程技术,以Microsoft数据访问
对象(DAO)模型为基础,结合使用Microsoft AcceSS数据库创建
工具,创建了专家系统的知识库。同时,论文中还介绍了本专家
系统的使用方法和相关说明。
本系统具有界面友好、操作简单、人机交互性能好、自动化
程度高、具备一定的推理能力等特点,具有广阔的应用前景。
Jigging separation is an important way of coal processing . As the key device of jigger, the reliability of electromagnetic air-valve affects the function of the whole machine, and the automatic control of air-valve is the important part of the automatic control of the jigger. Jigging process is very complex, and all the factors affect each other, jigger driver must adjust the air-valve parameters based on material, volume, wind pressure, bed thickness and his own experience. People are concerned with the control process, which is difficult for the normal control method. So the automatic control of air-valve need intelligent control method, and need import human knowledge and intelligence into control system.
This article gives expert system control of jigging air-valve. Expert system is an intelligent reasoning system based on knowledge, which combines artificial intelligence with domain knowledge, and is related to KA, database, reasoning system and interface between human and computer. Expert system is widely used , and can improve the working efficiency and quality. The knowledge comes from expert experience, field data and experiments. Expert system deduces intelligently based on feedback bed-layer density and buoyages signals and expert knowledge, and then modifies the air-valve parameters accordingly, so we can get the right air-valve parameters.
Windows 2000 is the development platform of this expert system, and Visual Basic 6.0 is the development tool, so we get the whole expert system. We make use of object-oriented programming technique based on DAO model and set up the repository of expert system using Microsoft Access database. At the same time this article gives the operating method of the expert system. This system has some characters, such as friendly interface, easy operation, good intercommunion between human and computer, topping automatism, good reasoning ability. So the system has beautiful future.
本论文提出了一种跳汰机风阀的专家系统自动调控方法。专家系统是基于知识的智能推理系统,集人工智能和领域知识于一体,涉及到知识获取、知识库、推理机制以及智能人—机交互界面的研究,已在众多领域获得广泛应用,大大提高了工作效率和工作质量,促进了人类智能和机器智能的相互补充和相互渗透。本专家系统的专家知识来源于选煤专家经验及跳汰机操作人员
太原理工大学硕士研究生学位论文
长期积累的经验、现场数据分析和实验总结等。专家系统会根据
实时采集反馈回的现场床层的密度和浮标等信号,基于获取的专
家知识,调用推理规则,进行智能推理,实现对风阀参数适当的
修改,从而得到合理的风阀参数。
本专家系统以WindowS 2000为开发平台,以面向对象的编程
工具VISual Basic 6.0为开发工具,实现了整个专家系统的软件
编程。使用面向对象的数据库编程技术,以Microsoft数据访问
对象(DAO)模型为基础,结合使用Microsoft AcceSS数据库创建
工具,创建了专家系统的知识库。同时,论文中还介绍了本专家
系统的使用方法和相关说明。
本系统具有界面友好、操作简单、人机交互性能好、自动化
程度高、具备一定的推理能力等特点,具有广阔的应用前景。
Jigging separation is an important way of coal processing . As the key device of jigger, the reliability of electromagnetic air-valve affects the function of the whole machine, and the automatic control of air-valve is the important part of the automatic control of the jigger. Jigging process is very complex, and all the factors affect each other, jigger driver must adjust the air-valve parameters based on material, volume, wind pressure, bed thickness and his own experience. People are concerned with the control process, which is difficult for the normal control method. So the automatic control of air-valve need intelligent control method, and need import human knowledge and intelligence into control system.
This article gives expert system control of jigging air-valve. Expert system is an intelligent reasoning system based on knowledge, which combines artificial intelligence with domain knowledge, and is related to KA, database, reasoning system and interface between human and computer. Expert system is widely used , and can improve the working efficiency and quality. The knowledge comes from expert experience, field data and experiments. Expert system deduces intelligently based on feedback bed-layer density and buoyages signals and expert knowledge, and then modifies the air-valve parameters accordingly, so we can get the right air-valve parameters.
Windows 2000 is the development platform of this expert system, and Visual Basic 6.0 is the development tool, so we get the whole expert system. We make use of object-oriented programming technique based on DAO model and set up the repository of expert system using Microsoft Access database. At the same time this article gives the operating method of the expert system. This system has some characters, such as friendly interface, easy operation, good intercommunion between human and computer, topping automatism, good reasoning ability. So the system has beautiful future.
引文
[1] 陈迹.跳汰选煤的理论与实践.北京.煤炭工业出版社.1988(11):177~327
[2] 李贤国,张荣曾,重力选矿原理.北京.煤炭工业出版社.1992(4):125~147
[3] 张鸿起.刘顺,王振生,重力选矿.北京.煤炭工业出版社.1987(10):165~217
[4] 张家骏,霍旭红编著.物理选矿.北京.煤炭工业出版社.1992(10):206~253
[5] 霍森等,跳汰分选过程控制的现状及发展,中国煤炭,1998,Vol.24,No.9,25~26
[6] 李洪庆,屈盛安,钟会平,跳汰机风阀自动控制.选煤技术.1995(5):20~25
[7] 陈宗海.智能自动化技术的现状与发展趋势.自动化博览.2000(2):4~7
[8] 李军利,黄艳芳,熊诗波.跳汰机电磁风阀的PLC控制.煤矿机械.2001(2):47~48
[9] 杨小平,跳汰机控制系统的设计,煤炭工程,2001,Vol.223,No.7,24-26
[10] 马方清,丁恩杰,等.跳汰机选煤生产过程智能控制.中国矿业大学学报.2002(3):293~296
[11] 费耕.跳汰机自动控制若干技术的研究与实现.煤炭科学技术.1994(22):30-35
[12] 陈迹.跳汰床层分布规律及产品分离理论.煤炭学报.1982,7(3):57~66
[13] 罗公亮,卢强.智能控制与常规控制.自动化学报.1994,20(3):324~328
[14] 林明星,张永忠,杜长龙等.跳汰机床层松散度的计算机检测系统.煤矿机电.2000(2):9~11
[15] 贾建新.跳汰机床层参数之间相互关系的研究.煤炭加工与综合利用.2002(2):52~56
[16] 顾年定.跳汰机床层自动跟踪系统新方案.矿山机械.2000(1):46~49
[17] 姚昆亮.自动化跳汰机研究.选煤技术.1999,8(4):5~7
[18] 李志宏等,基于VB的PLC和上位机通信的实现方法,基础自动化,2002,Vol.9,No.1,35-37
[19] 于海波,於春慧,高建国等.跳汰机实时分选密度测控及灰分闭环控制的探讨.选煤技术.2002,4(2):16~20
[20] 林明星,张永忠,杜长龙等.跳汰床层适当松散的表示形式及检测方法.矿山机械.2000(4):34~38
[21] 鲁杰,刘德华等.灰色预测控制与跳汰机主要工艺参数自动控制系统.选煤技术.2002,4(2):46~49
[22] 贾建新.跳汰机床层参数之间相互关系的研究.煤炭加工与综合利用.2002(2):25~26
[23] 徐志强,皇甫京华等.跳汰机工艺参数检测与控制.东北煤炭技术.1997,10(5):44~46
[24] 于海波等.跳汰机自动控制系统中自动给煤的研究与实践.煤炭科学技术.1999(3):16-19
[25] 孔力,程晶晶,钟志平等.γ射线透射组分测量的动态误差分析.选煤技术.2001,4(2):5~9
[26] 刘志伟.跳汰机床层状态检测和可视化.[学位论文] .山西太原.太原理工大学.1998
[27] 符东旭.跳汰机分层状态检测与控制的研究.[学位论文] .山西太原.太原理工大学.2000
[28] 符东旭,跳汰机自动控制的途径,选煤技术,1998,Vol.9,No.1,21-22
[29] 曾伟民,邓勇刚.Visual Basic 6.0高级实用教程.电子工业出版社.2000.4
[30] SIMENS可编程程序控制器手册.1997
[31] 张金涛.采矿方法选择专家系统.昆明理工大学学报.1994(5):20~22
[32] 顾年定.跳汰机床层自动跟踪系统新方案.矿山机械.2000(1):46~49
[33] 姚昆亮.自动化跳汰机研究.选煤技术.1999,8(4):5~7
[34] 冯博琴.实用专家系统.电子工业出版社.1994:35~60
[35] 朱福喜,汤怡群,傅建明.人工智能原理.武汉.武汉大学出版社.2002(2).192~207
[36] 林明星,张永忠,杜长龙等.跳汰床层适当松散的表示形式及检测方法.矿山机械.2000(4):34~38
[37] 杨康,鲁杰,杨大海.跳汰机给煤和供风系统对分选过程的影响.煤炭加工与综合利用.1998(2):34~36
[38] 杨康,跳汰机常见问题分析及解决方案,煤质技术,1988,No.3,28-30
[39] 陈冬冰.基于专家系统的跳汰机风阀自动控制.[学位论文] .山西太原.太原理工大学.2003
[40] 常若葵.跳汰机风阀控制系统的研究.[学位论文] .山西太原.太原理工大学.2003
[41] Lyman,G..J,Review of Jigging Principle & Control Coal Preparation, 1992(11):145~165
[42] Rong,R.X etc,Jig performance analysis, vii, Australia Coal Preparation Conference
[43] Rong,R.X,Lyman,G..J,New energy dissipation theory of jig bed stratification,International Journal of Mineral Processing vol.37,No.3 189-207
[44] Rong, Rui X, Lyman,Geoffrey J,Effect of jigging time and air cycle on bed stratification in pilot scale Baum jig,Vol. 71,No. 115-123
[45] Mathworks Co.nnet.pdf of Matlab Toolbox Version 6.5,1999
[46] A.Jonkers etc, Numerical Modelling of Particle stratification batch jig, vii, Australia Coal Preparation Conference
[47] T Satish,S Bukkapatnam, et al. Chaotic neurons for online quality control in manufacturing[J] . Adv Manuf Technol, 1997(13):95~100.
[48] Rose D E. Appropriate uses of hybrid system. In: D S Touretzk-y et al. (eds.). Connectionist Models, Proc.1990 Summer School, Morgan Kaufmann, CA, 1991:277~286
[49] Bhavik R.Bakshi and George Stephanopoulos, WaveNet. A.Multiresolution, Hierarchical Neural Network with Localized Learning,AICHE Journal. 1993,1(39): 57~80
[50] Wang X,Mendal J M. Generating fuzzy roles by learning from examples[J] . IEEE, Transaction SMC, 1992,22(6): 1414~1427.
[51] MATLAB user's guide. The Mathworks,Inc. 1999
[2] 李贤国,张荣曾,重力选矿原理.北京.煤炭工业出版社.1992(4):125~147
[3] 张鸿起.刘顺,王振生,重力选矿.北京.煤炭工业出版社.1987(10):165~217
[4] 张家骏,霍旭红编著.物理选矿.北京.煤炭工业出版社.1992(10):206~253
[5] 霍森等,跳汰分选过程控制的现状及发展,中国煤炭,1998,Vol.24,No.9,25~26
[6] 李洪庆,屈盛安,钟会平,跳汰机风阀自动控制.选煤技术.1995(5):20~25
[7] 陈宗海.智能自动化技术的现状与发展趋势.自动化博览.2000(2):4~7
[8] 李军利,黄艳芳,熊诗波.跳汰机电磁风阀的PLC控制.煤矿机械.2001(2):47~48
[9] 杨小平,跳汰机控制系统的设计,煤炭工程,2001,Vol.223,No.7,24-26
[10] 马方清,丁恩杰,等.跳汰机选煤生产过程智能控制.中国矿业大学学报.2002(3):293~296
[11] 费耕.跳汰机自动控制若干技术的研究与实现.煤炭科学技术.1994(22):30-35
[12] 陈迹.跳汰床层分布规律及产品分离理论.煤炭学报.1982,7(3):57~66
[13] 罗公亮,卢强.智能控制与常规控制.自动化学报.1994,20(3):324~328
[14] 林明星,张永忠,杜长龙等.跳汰机床层松散度的计算机检测系统.煤矿机电.2000(2):9~11
[15] 贾建新.跳汰机床层参数之间相互关系的研究.煤炭加工与综合利用.2002(2):52~56
[16] 顾年定.跳汰机床层自动跟踪系统新方案.矿山机械.2000(1):46~49
[17] 姚昆亮.自动化跳汰机研究.选煤技术.1999,8(4):5~7
[18] 李志宏等,基于VB的PLC和上位机通信的实现方法,基础自动化,2002,Vol.9,No.1,35-37
[19] 于海波,於春慧,高建国等.跳汰机实时分选密度测控及灰分闭环控制的探讨.选煤技术.2002,4(2):16~20
[20] 林明星,张永忠,杜长龙等.跳汰床层适当松散的表示形式及检测方法.矿山机械.2000(4):34~38
[21] 鲁杰,刘德华等.灰色预测控制与跳汰机主要工艺参数自动控制系统.选煤技术.2002,4(2):46~49
[22] 贾建新.跳汰机床层参数之间相互关系的研究.煤炭加工与综合利用.2002(2):25~26
[23] 徐志强,皇甫京华等.跳汰机工艺参数检测与控制.东北煤炭技术.1997,10(5):44~46
[24] 于海波等.跳汰机自动控制系统中自动给煤的研究与实践.煤炭科学技术.1999(3):16-19
[25] 孔力,程晶晶,钟志平等.γ射线透射组分测量的动态误差分析.选煤技术.2001,4(2):5~9
[26] 刘志伟.跳汰机床层状态检测和可视化.[学位论文] .山西太原.太原理工大学.1998
[27] 符东旭.跳汰机分层状态检测与控制的研究.[学位论文] .山西太原.太原理工大学.2000
[28] 符东旭,跳汰机自动控制的途径,选煤技术,1998,Vol.9,No.1,21-22
[29] 曾伟民,邓勇刚.Visual Basic 6.0高级实用教程.电子工业出版社.2000.4
[30] SIMENS可编程程序控制器手册.1997
[31] 张金涛.采矿方法选择专家系统.昆明理工大学学报.1994(5):20~22
[32] 顾年定.跳汰机床层自动跟踪系统新方案.矿山机械.2000(1):46~49
[33] 姚昆亮.自动化跳汰机研究.选煤技术.1999,8(4):5~7
[34] 冯博琴.实用专家系统.电子工业出版社.1994:35~60
[35] 朱福喜,汤怡群,傅建明.人工智能原理.武汉.武汉大学出版社.2002(2).192~207
[36] 林明星,张永忠,杜长龙等.跳汰床层适当松散的表示形式及检测方法.矿山机械.2000(4):34~38
[37] 杨康,鲁杰,杨大海.跳汰机给煤和供风系统对分选过程的影响.煤炭加工与综合利用.1998(2):34~36
[38] 杨康,跳汰机常见问题分析及解决方案,煤质技术,1988,No.3,28-30
[39] 陈冬冰.基于专家系统的跳汰机风阀自动控制.[学位论文] .山西太原.太原理工大学.2003
[40] 常若葵.跳汰机风阀控制系统的研究.[学位论文] .山西太原.太原理工大学.2003
[41] Lyman,G..J,Review of Jigging Principle & Control Coal Preparation, 1992(11):145~165
[42] Rong,R.X etc,Jig performance analysis, vii, Australia Coal Preparation Conference
[43] Rong,R.X,Lyman,G..J,New energy dissipation theory of jig bed stratification,International Journal of Mineral Processing vol.37,No.3 189-207
[44] Rong, Rui X, Lyman,Geoffrey J,Effect of jigging time and air cycle on bed stratification in pilot scale Baum jig,Vol. 71,No. 115-123
[45] Mathworks Co.nnet.pdf of Matlab Toolbox Version 6.5,1999
[46] A.Jonkers etc, Numerical Modelling of Particle stratification batch jig, vii, Australia Coal Preparation Conference
[47] T Satish,S Bukkapatnam, et al. Chaotic neurons for online quality control in manufacturing[J] . Adv Manuf Technol, 1997(13):95~100.
[48] Rose D E. Appropriate uses of hybrid system. In: D S Touretzk-y et al. (eds.). Connectionist Models, Proc.1990 Summer School, Morgan Kaufmann, CA, 1991:277~286
[49] Bhavik R.Bakshi and George Stephanopoulos, WaveNet. A.Multiresolution, Hierarchical Neural Network with Localized Learning,AICHE Journal. 1993,1(39): 57~80
[50] Wang X,Mendal J M. Generating fuzzy roles by learning from examples[J] . IEEE, Transaction SMC, 1992,22(6): 1414~1427.
[51] MATLAB user's guide. The Mathworks,Inc. 1999