基于变流检测的智能瓦斯检测仪研究
|
摘要
目前用于煤矿井下瓦斯气体检测的检测仪主要有光干涉式、热导式、半导体气敏式、红外光谱吸收式、电化学式和载体催化燃烧式六种,广泛使用的载体催化瓦斯检测仪在检测高浓度瓦斯时,载体催化元件容易出现高温烧结的现象,致使传感器的灵敏度及测量的准确性变差。本研究在深入研究了载体催化元件特性后,提出了一种新型变流瓦斯检测技术,它使载体催化传感器在检测瓦斯气体时始终处于恒温状态,可以使瓦斯检测的稳定性、响应速度、瓦斯浓度检测范围、检测仪使用寿命等技术指标极大的优于传统电桥检测方法。
本研究主要介绍了变流检测技术瓦斯传感的设计方案,并就该系统的理论基础、新型变流瓦斯检测仪的实现方法、硬件和软件设计等做了详细的讨论。其中,硬件部分的研究包括变流检测电路、以AT89C51单片机为核心的数据处理单元及其外围电路、红外遥控接收电路等;软件部分包括主程序、脉冲占空比测量、零点漂移自校准、非线性修正、数据显示、片外存储器读写、频率信号输出等子程序。
本研究设计的变流瓦斯检测仪具有低功耗、高精度、宽量程、自动校零、校调周期长及使用寿命长等优点。将这种新型的瓦斯检测仪应用于煤矿安全监测监控系统中,可以连续的测量矿井瓦斯浓度,为煤矿安全生产提供了有力的保障,同时该瓦斯检测仪也肯定会有广阔的应用前景和良好的经济前景。
Currently, there are six types of detector used for gas detection under the coal mine, optical-interference type, thermal-conductivity type, semiconductor-gas-sensor type, infrared spectrum absorption type, electrochemical type and vector-catalytic-combustion type. When conventional carrier catalytic methane detector detects high methane concentration, supporter catalyst filled element often sinters caused by high temperature which could damage the sensibility and the precision of detector. Based on the research of frame and working principle of supporter catalyst filled element embedded, we advance a new type variable current detecting technique which the temperature of supporter catalyst filled element is steady. This cause the technical index, such as the stability, response speed, detecting bound and the using life, better then the traditional detection bridge method.
The paper mainly introduces the tentative design of the variable current detecting technique, and discusses in detail its theoretical foundation, implementary method and the design of hard and software. The study of hardware circuits includes variable current detecting circuit、AT89C51 data processing circuit and its circumambient circuit、infrared remote control circuit and so on; the part of software includes main program, zero-adjusting program, non-linear correcting program, data showing program, extending memorizer reading and writing program, frequency signal output program.
The new type detector has some features, such as low power、high precision、wide range、automatic zero adjustment、long check-verifying period and long using life. If this new type methane sensor used in the system of monitoring mining safety, this can detects continuous methane concentration and ensures the yielding security of coal mine. Also this new type sensor has a bright prospect for development and application, a good economic prospect.
本研究主要介绍了变流检测技术瓦斯传感的设计方案,并就该系统的理论基础、新型变流瓦斯检测仪的实现方法、硬件和软件设计等做了详细的讨论。其中,硬件部分的研究包括变流检测电路、以AT89C51单片机为核心的数据处理单元及其外围电路、红外遥控接收电路等;软件部分包括主程序、脉冲占空比测量、零点漂移自校准、非线性修正、数据显示、片外存储器读写、频率信号输出等子程序。
本研究设计的变流瓦斯检测仪具有低功耗、高精度、宽量程、自动校零、校调周期长及使用寿命长等优点。将这种新型的瓦斯检测仪应用于煤矿安全监测监控系统中,可以连续的测量矿井瓦斯浓度,为煤矿安全生产提供了有力的保障,同时该瓦斯检测仪也肯定会有广阔的应用前景和良好的经济前景。
Currently, there are six types of detector used for gas detection under the coal mine, optical-interference type, thermal-conductivity type, semiconductor-gas-sensor type, infrared spectrum absorption type, electrochemical type and vector-catalytic-combustion type. When conventional carrier catalytic methane detector detects high methane concentration, supporter catalyst filled element often sinters caused by high temperature which could damage the sensibility and the precision of detector. Based on the research of frame and working principle of supporter catalyst filled element embedded, we advance a new type variable current detecting technique which the temperature of supporter catalyst filled element is steady. This cause the technical index, such as the stability, response speed, detecting bound and the using life, better then the traditional detection bridge method.
The paper mainly introduces the tentative design of the variable current detecting technique, and discusses in detail its theoretical foundation, implementary method and the design of hard and software. The study of hardware circuits includes variable current detecting circuit、AT89C51 data processing circuit and its circumambient circuit、infrared remote control circuit and so on; the part of software includes main program, zero-adjusting program, non-linear correcting program, data showing program, extending memorizer reading and writing program, frequency signal output program.
The new type detector has some features, such as low power、high precision、wide range、automatic zero adjustment、long check-verifying period and long using life. If this new type methane sensor used in the system of monitoring mining safety, this can detects continuous methane concentration and ensures the yielding security of coal mine. Also this new type sensor has a bright prospect for development and application, a good economic prospect.
引文
[1]黄继昌,徐巧鱼,传感器工作原理及应用事例[M].人民邮电出版社.1998
[2]王君,凌振宝.传感器原理及检测技术[M].长春:吉林大学出版社,2003:267~290.
[3]邹德蕴,张广文.矿井环境气体理化性与控制技术[M].北京:煤炭工业出版社, 2002.
[4]何希才.传感器及其应用[M].北京:国防工业出版社,2001
[5]唐露新.传感与检测技术[Ml.北京:科学出版社,2006
[6] J.P. Silveira, J. Anguita, F. Briones, etal. Micromachined methane sensor based on low resolution spectral modulation of IR absorption radiation. Sensors and Actuators [B],1998(48):305~307.
[7] Rego. A.Mendesi, Carbon dioxide/methane gas sensor base on the perm selectivity of polymeric membranes for biogas monitoring:Sensors and Actuators[B],2004(103): 2~6
[8] L.N.van Rij. R.C. van Landschoot. J.Schoonman, Detection of methane in oxygen-poor atmospheres using a catalytic sensor design.Sensors and Actuators[B],2001(75):111~120
[9]刘迎春.传感器原理设计及应用[M].哈尔滨工业大学出版社,1989
[10]煤炭工业部.煤矿用低浓度载体催化式CH4传感器技术条件,1996
[11]刘俊华.智能传感器系统[M].西安:西安电子科技大学出版社,1999
[12]付华,郭虹,徐耀松.智能仪器设计[M].北京:国防工业出版社,2007
[13]欧阳文.ATMEL89系列单片机的原理与开发实践[M].中国电力出版社,2007
[14]王为青,程国钢.单片机Keil Cx51应用开发技术[M].人民邮电出版社,2007
[15]李承烈,李贤均,张国泰.催化剂失活[M].北京:化学工业出版社,1989:117~118
[16] Zhang Hongquan Study on the CO micro gas sensor with temperature and humidity compensation[C] China:6th International Symposium on Test and Measurement,2005:3715~3718
[17]沈红卫.基于单片机的智能系统设计与实现[M].电子工业出版社,2005
[18]余永权.ATMEL89系列单片机应用技术[M].北京:北京航空航天大学出版社,1997
[19]何立民.I2C总线应用系统设计[M].北京:北京航空航天大学出版社,1995
[20]李巍,黄世震,陈文哲.CH4气体传感元件的研究现状与发展趋势[J].福建工程学院学报,2006(1):4~8
[21]周航慈.单片机程序设计技术[M].北京:北京航空航天大学出版社,1991
[22]刘光斌,刘冬,姚志成.单片机系统实用抗干扰技术[M].人民邮电出版社,2003
[23]蔡美琴,张为民等.MCS-51系列单片机系统及其应用(第二版)[M].高等教育出版社.2004
[24]王汝琳.矿井环境传感技术[M].中国矿业大学出版社.1998
[25]边春远,王志强.MCS-51单片机应用开发实用子程序[M].人民邮电出版社,2005
[26]刘志存.催化元件变流检测矿井瓦斯[J].传感器技术,2003(11)
[27]肖鸣,陈岱.光干涉法实现CH4浓度的直读式测量[J].国内科技,1999(2):37~38.
[28]王汝林.矿井瓦斯传感器的近代研究方法及方向[J].煤矿自动化,1998(4):16~18
[29]王汝林.载体催化元件特性的研究[J].中国矿业学院学报,1982(1):21~31
[30]曹贵良.LXK系列催化元件的稳定性[J].舰船科学技术,2001(3):33~36
[31]周军民.耿村煤矿“1.25”特大瓦斯爆炸原因及防范措施[J].煤矿安全,2001 (3):32~33.
[32]张洪泉,郭建英,施云波.热燃烧式瓦斯传感器催化剂失活机理研究[J].传感器与微系统,2007(1):45~47
[33]刘建周,徐正新,刘凤丽.CH4催化元件输出漂移的原因分析与对策[J].传感器技术,2004(6):55~57
[34]范振兴.煤矿CH4测量原理及其常见故障分析[J].陕西煤炭技术,1999(1):51~56
[35]孙江波.单片机I2C串行总线原理及其应用编程[J].武汉工业学院学报,1999(4):82~86
[36]童明敏,杨胜强,田丰.新型瓦斯传感器关键技术的研究[J].中国矿业大学学报,1982(1):21~31
[37]纪宗南.红外遥控发射器的原理及应用[J].国外电子元器件.1999(10):32~34
[38]邱文静.基于GSM短信息的家具设施遥控监测系统设计[硕士学位论文].南京理工大学
[39]孔娟.单片机测控系统中的抗干扰技术[J].自动化与仪器仪表,2003(3):31~45
[40]汪胜聪,腾勤,左承基.综述单片机控制系统的抗干扰设计[J].现代电子技术,2003(1): 7~9
[41]龚孟君,陈锡洪.影响瓦斯传感器稳定性的原因及改善途径[J].煤矿自动化,1996(2):32~34
[42]朱正和.黑黑元件的研究[J].矿业安全与环保.2004(1):6~9
[43]电子工程手册编委会编.中外集成电路简明速查手册.电子工业出版社.1991
[44]童敏明.恒温瓦斯检测的动态分析[J].中国矿业大学学报.2000.5
[45]张志刚,王汝琳,张志丰.载体催化传感器的电压特性曲线[J].煤矿自动化.2000(10)
[46] AT89C51,8-bit Microcontroller with 4KB In-System Programmable Flash,ATMEL Corporation.1998
[47]蒋磊,刘芳华.催化燃烧型CH4传感器恒温检测桥路的研究[J].工矿自动化,2006(12)
[48] ATMEL Corporation AT89/AT89S/AT90S Series Flash Microcontrollers Development Tools User Guide ATMEL Corporation.1997
[49]刘建周,范健,王小刚等.CH4催化燃烧反应与CH4传感器稳定性的研究[J].煤炭转化,1998(1):87~90
[50]陈新军,刘明光.基于单片机的煤矿瓦斯自动检测系统[J].采矿技术.2007(3):75~76
[51]丁黎明,赵景波.催化燃烧型CH4传感器的研究[J].微计算机信息,2007(1):177~178
[52]安敏.瓦斯监控系统的研制.[硕士学位论文].重庆大学2002
[53]谢宝伟,李国斌.催化燃烧型瓦斯检测仪器性能特征及影响因素浅析[J].煤矿安全,2002,33(3):54~55
[54]朱正和.提高CH4载体催化元件灵敏度的研究[J].矿业安全与环保,2003,30(6): 21~22
[2]王君,凌振宝.传感器原理及检测技术[M].长春:吉林大学出版社,2003:267~290.
[3]邹德蕴,张广文.矿井环境气体理化性与控制技术[M].北京:煤炭工业出版社, 2002.
[4]何希才.传感器及其应用[M].北京:国防工业出版社,2001
[5]唐露新.传感与检测技术[Ml.北京:科学出版社,2006
[6] J.P. Silveira, J. Anguita, F. Briones, etal. Micromachined methane sensor based on low resolution spectral modulation of IR absorption radiation. Sensors and Actuators [B],1998(48):305~307.
[7] Rego. A.Mendesi, Carbon dioxide/methane gas sensor base on the perm selectivity of polymeric membranes for biogas monitoring:Sensors and Actuators[B],2004(103): 2~6
[8] L.N.van Rij. R.C. van Landschoot. J.Schoonman, Detection of methane in oxygen-poor atmospheres using a catalytic sensor design.Sensors and Actuators[B],2001(75):111~120
[9]刘迎春.传感器原理设计及应用[M].哈尔滨工业大学出版社,1989
[10]煤炭工业部.煤矿用低浓度载体催化式CH4传感器技术条件,1996
[11]刘俊华.智能传感器系统[M].西安:西安电子科技大学出版社,1999
[12]付华,郭虹,徐耀松.智能仪器设计[M].北京:国防工业出版社,2007
[13]欧阳文.ATMEL89系列单片机的原理与开发实践[M].中国电力出版社,2007
[14]王为青,程国钢.单片机Keil Cx51应用开发技术[M].人民邮电出版社,2007
[15]李承烈,李贤均,张国泰.催化剂失活[M].北京:化学工业出版社,1989:117~118
[16] Zhang Hongquan Study on the CO micro gas sensor with temperature and humidity compensation[C] China:6th International Symposium on Test and Measurement,2005:3715~3718
[17]沈红卫.基于单片机的智能系统设计与实现[M].电子工业出版社,2005
[18]余永权.ATMEL89系列单片机应用技术[M].北京:北京航空航天大学出版社,1997
[19]何立民.I2C总线应用系统设计[M].北京:北京航空航天大学出版社,1995
[20]李巍,黄世震,陈文哲.CH4气体传感元件的研究现状与发展趋势[J].福建工程学院学报,2006(1):4~8
[21]周航慈.单片机程序设计技术[M].北京:北京航空航天大学出版社,1991
[22]刘光斌,刘冬,姚志成.单片机系统实用抗干扰技术[M].人民邮电出版社,2003
[23]蔡美琴,张为民等.MCS-51系列单片机系统及其应用(第二版)[M].高等教育出版社.2004
[24]王汝琳.矿井环境传感技术[M].中国矿业大学出版社.1998
[25]边春远,王志强.MCS-51单片机应用开发实用子程序[M].人民邮电出版社,2005
[26]刘志存.催化元件变流检测矿井瓦斯[J].传感器技术,2003(11)
[27]肖鸣,陈岱.光干涉法实现CH4浓度的直读式测量[J].国内科技,1999(2):37~38.
[28]王汝林.矿井瓦斯传感器的近代研究方法及方向[J].煤矿自动化,1998(4):16~18
[29]王汝林.载体催化元件特性的研究[J].中国矿业学院学报,1982(1):21~31
[30]曹贵良.LXK系列催化元件的稳定性[J].舰船科学技术,2001(3):33~36
[31]周军民.耿村煤矿“1.25”特大瓦斯爆炸原因及防范措施[J].煤矿安全,2001 (3):32~33.
[32]张洪泉,郭建英,施云波.热燃烧式瓦斯传感器催化剂失活机理研究[J].传感器与微系统,2007(1):45~47
[33]刘建周,徐正新,刘凤丽.CH4催化元件输出漂移的原因分析与对策[J].传感器技术,2004(6):55~57
[34]范振兴.煤矿CH4测量原理及其常见故障分析[J].陕西煤炭技术,1999(1):51~56
[35]孙江波.单片机I2C串行总线原理及其应用编程[J].武汉工业学院学报,1999(4):82~86
[36]童明敏,杨胜强,田丰.新型瓦斯传感器关键技术的研究[J].中国矿业大学学报,1982(1):21~31
[37]纪宗南.红外遥控发射器的原理及应用[J].国外电子元器件.1999(10):32~34
[38]邱文静.基于GSM短信息的家具设施遥控监测系统设计[硕士学位论文].南京理工大学
[39]孔娟.单片机测控系统中的抗干扰技术[J].自动化与仪器仪表,2003(3):31~45
[40]汪胜聪,腾勤,左承基.综述单片机控制系统的抗干扰设计[J].现代电子技术,2003(1): 7~9
[41]龚孟君,陈锡洪.影响瓦斯传感器稳定性的原因及改善途径[J].煤矿自动化,1996(2):32~34
[42]朱正和.黑黑元件的研究[J].矿业安全与环保.2004(1):6~9
[43]电子工程手册编委会编.中外集成电路简明速查手册.电子工业出版社.1991
[44]童敏明.恒温瓦斯检测的动态分析[J].中国矿业大学学报.2000.5
[45]张志刚,王汝琳,张志丰.载体催化传感器的电压特性曲线[J].煤矿自动化.2000(10)
[46] AT89C51,8-bit Microcontroller with 4KB In-System Programmable Flash,ATMEL Corporation.1998
[47]蒋磊,刘芳华.催化燃烧型CH4传感器恒温检测桥路的研究[J].工矿自动化,2006(12)
[48] ATMEL Corporation AT89/AT89S/AT90S Series Flash Microcontrollers Development Tools User Guide ATMEL Corporation.1997
[49]刘建周,范健,王小刚等.CH4催化燃烧反应与CH4传感器稳定性的研究[J].煤炭转化,1998(1):87~90
[50]陈新军,刘明光.基于单片机的煤矿瓦斯自动检测系统[J].采矿技术.2007(3):75~76
[51]丁黎明,赵景波.催化燃烧型CH4传感器的研究[J].微计算机信息,2007(1):177~178
[52]安敏.瓦斯监控系统的研制.[硕士学位论文].重庆大学2002
[53]谢宝伟,李国斌.催化燃烧型瓦斯检测仪器性能特征及影响因素浅析[J].煤矿安全,2002,33(3):54~55
[54]朱正和.提高CH4载体催化元件灵敏度的研究[J].矿业安全与环保,2003,30(6): 21~22