矿山井下主配设备安全预警关键技术研究
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摘要
摘要:矿山井下设备是矿山生产作业的重要支柱,其井下配套的矿井通风机设备系统、矿井提升机设备系统、矿井排水设备系统及井下空压机设备系统是矿山井下生产必备的主要配套设备,简称为矿山井下主配设备系统。其井下主配设备系统工作运行的好坏直接关系到矿山人员安全及生产安全和效益,因此如何实现和保障其井下主要关键设备的安全可靠运行,一直是矿山安全生产领域的重要研究课题。目前,在井下矿山单设备系统监测监控领域及井下瓦斯监控方面国内外已有了不少研究成果,但基于包含井下多设备安全监控系统及兼容井下瓦斯监控等井下其它安全监控系统的集成化统一监控平台系统的研究稀有涉及,本文正是基于上述现实问题,提出矿山井下安全预警统一监控平台研究课题,并对形成安全预警统一监控平台系统的主要关键技术问题展开理论研究与技术实现。
研究设计了包含矿山井下四大主配设备系统的统一的从井下到井上的三层监控组网技术方案,其组网技术方案首次包含老旧监控设备系统的兼容、包含瓦斯传感器检测及井下人员定位检测系统等扩展接口功能,此组网方案及技术实现在国内首创,为后继矿山安全监控水平的提升提供了全新的理念。
针对矿山井下四大主要配套设备系统各自的功能分析及选用的安全监控参数及工艺控制方式,本论文统一的对其进行了详细归纳与研究,提出了统一安全监控平台经济适用、性价比高的参数组选型原则方案。
通过对统一监控平台所需要的各类电量与非电量传感器性能的分析,研究了传感器的组成、发展、现状,性能特性及传感器技术的飞速发展趋势所带来的组网用传感器选型的困惑,提出了矿山井下安全监控用系统传感器在工程实例中的主要选用原则。
通过SVM数值分析技术手段对矿山回采工作面的瓦斯传感器的放置位置与放置数量进行数值分析,验证了瓦斯传感器放置位置距离及传感器数量问题。
通过对以往各类控制技术等的全面分析研究,给出了以PLC开发环境作为分布式子站控制器方案的最优结论,研究开发出预警监控平台分布式子站现场监控系统最佳组网技术方案结构框图。研究总结出PLC硬件配型原则,并进行了配型实现,通过软件编程实现了PLC开发环境下的井下风机等系统的自动监测控制。
针对井下特殊环境下数据安全采集的高要求,研究分布式子站传感器与工业控制器之间数据安全采集的实现方法,提出了适合井下数据安全采集与传输的统一的安全电量变送器联接概念,用于解决大监控平台多类型传感器多源信息融合难的问题,开发设计出数据安全采集系统框图。
利用现有的井上监控平台、分布于井下的组网综合布线系统及井下控制器系统,研究与探讨了预警监控平台兼容瓦斯监控、人员定位及井下老旧设备系统的一种扩展兼容接口技术实现解决方案,给出了分布式子站扩展兼容接口相应技术实现设计方案。
将井上光纤以太网通信技术与井下CAN总线通信技术相结合的组网方式应用到多设备系统的监控平台上,通过设计两种通用的通信智能节点,很好的解决了多设备监控系统信道不共享、协议不兼容等问题。
选择组态王为本矿山主配设备预警监控平台上位机软件开发环境,完成井下各设备系统中控制器与上位机软件监控系统的数据对接设计,完成矿山井下主配设备预警监控平台软件监控系统主界面及各分系统界面的软件编程实现。
采用数据库技术应用于矿山井下多设备系统的统一监控平台当中,通过将数据库与监控平台各层监控软件进行数据对接,并利用其数据库技术对海量数据的数据分析与数据管理优势,解决了目前统一矿山监控平台软件难以满足多设备系统庞大数据实时监控处理的难题。
建立了上位机监控平台界面,其显示功能首次包含了平台主监控界面、各主配设备分系统监控界面,并建立了井下各子站现场监控界面,系统包含了全方位监控功能,建立了从井下到井上的全方位、实时、立体、安全的监控防护体系。
本文在矿山井下安全监控系统中综合了目前几大前沿技术,将其各自的优势发挥于矿山井下多设备系统统一监控的平台之中,这些技术包括最新的控制技术、最新的组网技术、最新的通信技术以及最新的软件监控技术,为后继矿山井下设备、人员及瓦斯安全监控设计者提供全新的可实施的操作方案。
本文所做研究工作,立足于学科前沿,对矿山井下主要配套设备安全预警关键技术问题进行了较深入的研究,具有重要的理论意义和工程应用价值。图96幅,表1个,参考文献219篇
ABSTRACT:Mine underground equipment is an important pillar of mining production. Its mine ventilator equipment system, mine hoist equipment system, mine drainage equipment system and mine air compressor equipment system, wholly named as underground main configuration equipment system, are indispensable for mine production of major equipment. The stand or fall of its main configuration equipment system is directly related to the miners'safety, production safety and benefit, so how to realize and safeguard its key equipments in safe and reliable operation has always been an important research topic in the field of mine safety production. At present, a lot of researches into the field of underground mining equipment's monitoring and fault diagnosis have got results, but less researches have been done on an integrated monitoring platform which can unify the multiply underground safety monitoring systems and gas control and other safety monitoring system. Based on this reality, this paper puts forward the topic on an integrated pre-warning and monitoring platform of mine underground equipment and further does some theoretical researches and technological practice on main technologies concerning the safety pre-warning and monitoring platform system.
The paper designs an unified technological networking project of three monitoring layers which covers the main four underground configuration equipment systems from the underground to the surface. This networking project originally includes the compatibility of the old monitoring systems, the gas sensor checking and some expanding connection functions such as the miners underground positioning systems. This network design and the technological realization is initiatively mentioned in China which provides a new concept for promoting the level of further underground safety monitoring.
This paper, for the first time, has a detailed induction and research on the functional analysis of the main four auxiliary equipment systems respectively and the selected safety monitoring parameters and process control and then puts the priority to the parameters project with its affordable, cost-effective unified safety monitoring platform.
Through the analysis on performance of all kinds of electric and non electric sensors needed in the unified monitoring platform as well as the studies of composition, development, status of sensor network, the trend of rapid development of performance characteristics and confusion about the sensor selection, this paper puts forward the main selection principle of safety monitoring system for underground mine sensor in the engineering practical cases.
Based on the numerical analysis of gas sensor position and the amounts placed on the mine working place by adopting SVM numerical analysis technology, it verifies gas sensor placement distance and the quantities of sensors.
Through a comprehensive analysis of previous research of various kinds of control technology, this paper presents an optimal conclusion, that is, taking PLC development environment as a distribution sub-station controller and then studies and develops an optimal network technology program diagram of field monitoring system about monitoring and early warning platform distributed sub-station. This study concludes the matching principle of PLC hardware and the realization of matching. The automatic monitoring and control of the underground mine fan system under the PLC development environment is realized by software programming.
In view of the high requirements of data collection safely in the special underground environment, after studying the distributed sub-station data security system between the sensor and the industrial controller, the concept of unified connection of safety electric transducer has been put forward for underground data acquisition and transmission which is used to solve the fusion problems about multiply information from monitoring platform, and further develops block diagram of safety data acquisition system.
Based on the existing wells monitoring platform and the network cabling system and downhole controller system distributed in underground, it studies and discusses the monitoring and early warning platform compatible with an extended gas monitoring, underground personnel positioning and old equipment system solutions compatible interface technology, presents the distribution sub-station expansion implementation design of interface technology.
Applying the network technology to the monitoring platform of multi equipment system by combining the Ethernet communication technology of well fibers and downhole CAN bus communication technology, through the design of two kinds of general intelligent node, it can solve the problems of no compatibility and no acceptable sharing channels in multi-equipment monitoring system.
Selecting the Kingview as the main software developing environment on the host computer for mine monitoring and early warning platform, it completes docking of data from the controllers of every equipment system and PC software monitoring system of the host computer, completes software programming of mineral main equipment monitoring and early warning platform software monitoring system for the main interface and the sub interface of the system.
In unified monitoring platform by application of database technology in the mine equipment system, the database and the monitoring platform of each layer of monitoring software have the data docking, and by using the database technology of massive data analysis and data management advantages, the united mine monitoring platform software is to solve the problem of huge data real-time monitoring system processing with multiply equipments.
Setting up a monitoring platform in the computer interface on which the screen display includes the main monitoring interface, the main distribution equipment system and control interface for the first time. Establishing a real-time monitoring platform of underground sub interface, this system includes the all-round monitoring function and has established a full range, real-time, three-dimensional security monitoring and protection system from the underground to the well.
This paper comprehensively covers several cutting-edge technologies in safety monitoring system in underground mines, to play their respective advantages in underground mines unified monitoring equipment system platform. These technologies include control technology, the network technology, the new communication technology of the latest and most new software monitoring technology. This paper provides the operation scheme of new implementation for future mine equipment, personnel and gas safety monitoring designs.
Based on the frontier, this paper has conducted a thorough research into the key technology problems of security early warning of mine main equipment and it has important theory significance and engineering application value.
研究设计了包含矿山井下四大主配设备系统的统一的从井下到井上的三层监控组网技术方案,其组网技术方案首次包含老旧监控设备系统的兼容、包含瓦斯传感器检测及井下人员定位检测系统等扩展接口功能,此组网方案及技术实现在国内首创,为后继矿山安全监控水平的提升提供了全新的理念。
针对矿山井下四大主要配套设备系统各自的功能分析及选用的安全监控参数及工艺控制方式,本论文统一的对其进行了详细归纳与研究,提出了统一安全监控平台经济适用、性价比高的参数组选型原则方案。
通过对统一监控平台所需要的各类电量与非电量传感器性能的分析,研究了传感器的组成、发展、现状,性能特性及传感器技术的飞速发展趋势所带来的组网用传感器选型的困惑,提出了矿山井下安全监控用系统传感器在工程实例中的主要选用原则。
通过SVM数值分析技术手段对矿山回采工作面的瓦斯传感器的放置位置与放置数量进行数值分析,验证了瓦斯传感器放置位置距离及传感器数量问题。
通过对以往各类控制技术等的全面分析研究,给出了以PLC开发环境作为分布式子站控制器方案的最优结论,研究开发出预警监控平台分布式子站现场监控系统最佳组网技术方案结构框图。研究总结出PLC硬件配型原则,并进行了配型实现,通过软件编程实现了PLC开发环境下的井下风机等系统的自动监测控制。
针对井下特殊环境下数据安全采集的高要求,研究分布式子站传感器与工业控制器之间数据安全采集的实现方法,提出了适合井下数据安全采集与传输的统一的安全电量变送器联接概念,用于解决大监控平台多类型传感器多源信息融合难的问题,开发设计出数据安全采集系统框图。
利用现有的井上监控平台、分布于井下的组网综合布线系统及井下控制器系统,研究与探讨了预警监控平台兼容瓦斯监控、人员定位及井下老旧设备系统的一种扩展兼容接口技术实现解决方案,给出了分布式子站扩展兼容接口相应技术实现设计方案。
将井上光纤以太网通信技术与井下CAN总线通信技术相结合的组网方式应用到多设备系统的监控平台上,通过设计两种通用的通信智能节点,很好的解决了多设备监控系统信道不共享、协议不兼容等问题。
选择组态王为本矿山主配设备预警监控平台上位机软件开发环境,完成井下各设备系统中控制器与上位机软件监控系统的数据对接设计,完成矿山井下主配设备预警监控平台软件监控系统主界面及各分系统界面的软件编程实现。
采用数据库技术应用于矿山井下多设备系统的统一监控平台当中,通过将数据库与监控平台各层监控软件进行数据对接,并利用其数据库技术对海量数据的数据分析与数据管理优势,解决了目前统一矿山监控平台软件难以满足多设备系统庞大数据实时监控处理的难题。
建立了上位机监控平台界面,其显示功能首次包含了平台主监控界面、各主配设备分系统监控界面,并建立了井下各子站现场监控界面,系统包含了全方位监控功能,建立了从井下到井上的全方位、实时、立体、安全的监控防护体系。
本文在矿山井下安全监控系统中综合了目前几大前沿技术,将其各自的优势发挥于矿山井下多设备系统统一监控的平台之中,这些技术包括最新的控制技术、最新的组网技术、最新的通信技术以及最新的软件监控技术,为后继矿山井下设备、人员及瓦斯安全监控设计者提供全新的可实施的操作方案。
本文所做研究工作,立足于学科前沿,对矿山井下主要配套设备安全预警关键技术问题进行了较深入的研究,具有重要的理论意义和工程应用价值。图96幅,表1个,参考文献219篇
ABSTRACT:Mine underground equipment is an important pillar of mining production. Its mine ventilator equipment system, mine hoist equipment system, mine drainage equipment system and mine air compressor equipment system, wholly named as underground main configuration equipment system, are indispensable for mine production of major equipment. The stand or fall of its main configuration equipment system is directly related to the miners'safety, production safety and benefit, so how to realize and safeguard its key equipments in safe and reliable operation has always been an important research topic in the field of mine safety production. At present, a lot of researches into the field of underground mining equipment's monitoring and fault diagnosis have got results, but less researches have been done on an integrated monitoring platform which can unify the multiply underground safety monitoring systems and gas control and other safety monitoring system. Based on this reality, this paper puts forward the topic on an integrated pre-warning and monitoring platform of mine underground equipment and further does some theoretical researches and technological practice on main technologies concerning the safety pre-warning and monitoring platform system.
The paper designs an unified technological networking project of three monitoring layers which covers the main four underground configuration equipment systems from the underground to the surface. This networking project originally includes the compatibility of the old monitoring systems, the gas sensor checking and some expanding connection functions such as the miners underground positioning systems. This network design and the technological realization is initiatively mentioned in China which provides a new concept for promoting the level of further underground safety monitoring.
This paper, for the first time, has a detailed induction and research on the functional analysis of the main four auxiliary equipment systems respectively and the selected safety monitoring parameters and process control and then puts the priority to the parameters project with its affordable, cost-effective unified safety monitoring platform.
Through the analysis on performance of all kinds of electric and non electric sensors needed in the unified monitoring platform as well as the studies of composition, development, status of sensor network, the trend of rapid development of performance characteristics and confusion about the sensor selection, this paper puts forward the main selection principle of safety monitoring system for underground mine sensor in the engineering practical cases.
Based on the numerical analysis of gas sensor position and the amounts placed on the mine working place by adopting SVM numerical analysis technology, it verifies gas sensor placement distance and the quantities of sensors.
Through a comprehensive analysis of previous research of various kinds of control technology, this paper presents an optimal conclusion, that is, taking PLC development environment as a distribution sub-station controller and then studies and develops an optimal network technology program diagram of field monitoring system about monitoring and early warning platform distributed sub-station. This study concludes the matching principle of PLC hardware and the realization of matching. The automatic monitoring and control of the underground mine fan system under the PLC development environment is realized by software programming.
In view of the high requirements of data collection safely in the special underground environment, after studying the distributed sub-station data security system between the sensor and the industrial controller, the concept of unified connection of safety electric transducer has been put forward for underground data acquisition and transmission which is used to solve the fusion problems about multiply information from monitoring platform, and further develops block diagram of safety data acquisition system.
Based on the existing wells monitoring platform and the network cabling system and downhole controller system distributed in underground, it studies and discusses the monitoring and early warning platform compatible with an extended gas monitoring, underground personnel positioning and old equipment system solutions compatible interface technology, presents the distribution sub-station expansion implementation design of interface technology.
Applying the network technology to the monitoring platform of multi equipment system by combining the Ethernet communication technology of well fibers and downhole CAN bus communication technology, through the design of two kinds of general intelligent node, it can solve the problems of no compatibility and no acceptable sharing channels in multi-equipment monitoring system.
Selecting the Kingview as the main software developing environment on the host computer for mine monitoring and early warning platform, it completes docking of data from the controllers of every equipment system and PC software monitoring system of the host computer, completes software programming of mineral main equipment monitoring and early warning platform software monitoring system for the main interface and the sub interface of the system.
In unified monitoring platform by application of database technology in the mine equipment system, the database and the monitoring platform of each layer of monitoring software have the data docking, and by using the database technology of massive data analysis and data management advantages, the united mine monitoring platform software is to solve the problem of huge data real-time monitoring system processing with multiply equipments.
Setting up a monitoring platform in the computer interface on which the screen display includes the main monitoring interface, the main distribution equipment system and control interface for the first time. Establishing a real-time monitoring platform of underground sub interface, this system includes the all-round monitoring function and has established a full range, real-time, three-dimensional security monitoring and protection system from the underground to the well.
This paper comprehensively covers several cutting-edge technologies in safety monitoring system in underground mines, to play their respective advantages in underground mines unified monitoring equipment system platform. These technologies include control technology, the network technology, the new communication technology of the latest and most new software monitoring technology. This paper provides the operation scheme of new implementation for future mine equipment, personnel and gas safety monitoring designs.
Based on the frontier, this paper has conducted a thorough research into the key technology problems of security early warning of mine main equipment and it has important theory significance and engineering application value.
引文
[1]李承先.山西省地方煤矿矿井通风工作存在的问题及整改建议[J].山西煤炭,2003,25(1):45-47.
[2]Mutmansky J M,Wang A.Patterns of methane emission and their effects on mining costs in underground mining operations [J].Mihing Engineering, 1999,51(1):65-70.
[3]Brake D J,Rick D.Fan total pressure or fanstatic pressure:Which is correct when solving ventilation Problems[J].Mine ventilation Society of South Africa 2002,55(1):6-11.
[4]Lin Y X,Ma F Q,Cang X J.Three layer model for digital coal mine based on industrial ethernet[J].Collection of information and eleetrical engineering, 2008,30(2):1710-1714.
[5]Raina A,Ramulu M.Application of digital image analysis technique for assessment of blast fragmentation and explosives energy ultlisation in a large opencost coal mine[J].Transportation Research Board of the National Academics,2008,56(7):140-147.
[6]Zhang L,Xu Z,Yuan W C.Study on key technologies of digital mine integrated transmission Platform[C],ICIA2007:75-78.
[7]Trutwin W.Use of digital computers for the study of non-Steady states and automatic control problems in mine ventilation networks[J].International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 1972,9(2):289-323.
[8]孙英,近十年我国金属矿山通风系统的技术改造[J].金属矿山,1994,12(5):25-29.
[9]韩慧.矿井通风安全自动监测报警系统[D].青岛:山东科技大学,1999.
[10]海伦.煤矿信息化:信息产业新增长点[J].中国电子报,2005,23(4):34-36.
[11]李继培.煤矿井下灾害调查与研究[J].中国安全生产科学研究报,2005,24(7):23-25.
[12]冯晓芳.我国力推信息技术在煤矿安全领域应用[N].新华社北京,2005.10.03.
[13]米建国,李继培.依靠科技遏制瓦斯矿难[N].国务院发展研究中心信息中心,2005.08.02.
[14]Chen J Y,Zhang S,Zuo W R.Digital Coal Mine Integrated Automation System based on Controlnet[J]. Journal of China university of mining & technology, 2007,17(2):210-214.
[15]易志根.矿井通风监控系统设计与开发[硕士学位论文][D].长沙:中南大学,2010
[16]Wang Y J. Characteristics of multiple fan ventilation networks [J]. International journal of mining engineering,1984,12(2):229-243.
[17]Enb L M,Wang Y J.Characteristic curves revisited:a more logical approach to determining operating points [C], Mining Engineering (Lilttleton,Colorado), 1998:65-69.
[18]Wang Q F,Zhang X H.The digitization-emulation optimization and forecasting of mine ventilation system [J].Epic Consulting Services Ltd,2002, 12(6):480-484.
[19]Hardy C.The Influence of Mathematics on the Development of structural Form.Institute for Structural Design II,Germany,1935,23(4):212-221.
[20]赵梓成,谢贤平.矿井通风理论与技术进展评述[J].云南冶金,2002,31(3):24-31.
[21]Fu H,Shao L S.An optimized control of ventilation in coal mines based on artificial neual network. Journal of coal science & Engineering,2002, 8(2):80-83.
[22]Stefanko H,Baran A.Digital computer-based vibration monitoring in underground coal mine equipment [J].Senior Member of IEEE American Electric Powr 1988,35(6):1250-1254.
[23]Rastogi,Ven K.Digital control systems for mines and industrial Processes[J].Measurement Techniques,1984,1(2):21-28.
[24]沈斐敏.矿井通风系统合理性的综合评判[C].第二次全国采矿学术会议论文集(汇),1956(11):253-294.
[25]杨运良.矿井通风系统网路结构复杂程度的评价[J].煤矿安全,1998,29(1):321-334.
[26]李恕如,王义章.矿井通风网络图论[M].北京:煤炭工业出版社,1984:48-60,86-90.
[27]张惠忱.计算机在矿井通风中的应用[M].徐州:中国矿业大学出版,1992:62-234.
[28]赵以蕙.通风网络理论[M].北京:煤炭工业出版社,1993:66-81,161-179.
[29]王建浩,李承凯.管网故障微机诊断的实用方法[J].控制与测量,1999(2): 45-49.
[30]Le Gat Yves,Eisenbeis Patrick.Using maintenance records to forecast failures in water networks [J]. UrbanWater,2000,2(3):173-181.
[31]D.N.Shields,S.A.Ashton,S.Daley.Design of nonlinear observers for detecting faults in hydraulic sub-sea pipelines[J]. Control Engineering Praetice, 2001(9):297-311.
[32]梁建文,肖笛等.水管网故障实时诊断方法[J].水利学报,2001(12):40-47.
[33]税爱社,周绍骑.输油管线泄漏诊断的SCADA系统实现[D].仪器仪表学报,2001,22(4):229-230.
[34]龚晓燕,薛河,陶新利,孙晓辉.矿井局部通风故障诊断系统开发研究[J].煤炭工程,2008(2):128-130.
[35]黄雷.基于Web的矿井局部通风故障诊断专家系统[D].西安科技大学,2008:6-8.
[36]龚晓燕,孙晓辉.基于遗传算法的矿井局部通风故障诊断神经网络模型[J].煤矿安全,2008(2):35-38.
[37]赵丹.基于网络分析的矿井通风系统故障源诊断技术研究[博士学位论文][D].阜新:辽宁工程技术大学,2011.
[38]裴九芳.基于LabVIEW的矿井提升机监控系统[D].合肥:安徽理工大学,2005.
[39]荆双喜,赵玉峰,王建生.用噪声对提升机减速箱进行故障诊断[J].煤矿机械,1994,(3):27-29.
[40]肖兴明,黄小军,马小平等.矿井提升机监护系统的实现[J].仪表技术与传感器,1999(9):23-25.
[41]梁兆正,李文宏,肖林京,等.矿井提升机状态监测与故障诊断系统[J].矿山机械,1999,(3):38-41.
[42]张秀平.矿井提升机监测系统的研究与实现[J].工矿自动化,1999(1):23-24.
[43]付华,杨宝霖,高迎惠.基于多传感器信息融合的矿井提升机监测系统[J].辽宁工程技术大学学报(自然科学版),2001,20(1):60-62.
[44]黄民,李功,张永忠.矿井提升机振动测试与故障诊断[J].煤矿机械,2002(12):79-81.
[45]夏本春,周金荣,李至斌.提升机减速箱故障预报的实践[J].煤炭科技,2002,(1):36-37.
[46]刘可伟,杨兆建.基于人工神经网络的提升设备故障诊断研究[J].太原理工大学学报,2002,33(4):441-443.
[47]刘金琪,吕瑞丰.基于无线数据传输的钢丝绳张力监测系统[J].控制工程,2003,25(4):402-405.
[48]陈洁,杨兆建,高强.基于ANNES的矿井提升机故障诊断系统模型[J].机械管理开发,2004,77(2):14-15.
[49]王增才,聂志峰,邵海燕.多绳提升钢丝绳动态张力监测研究[J].仪器仪表学报,2004,10(3):364-372.
[50]王致杰,王崇林,卢文海等.煤矿提升机综合安全智能控制策略研究[C].第十五届全国煤矿自动化学术年会和中国煤炭学会煤矿自动化专业委员会学术会议论文集.第十五届全国煤矿自动化学术年会和中国煤炭学会煤矿自动化专业委员会学术会议.昆明:中国煤炭学会煤矿自动化专业委员会,2005.
[51]赵廷钊.提升机减速箱故障诊断技术研究[J].煤矿机电,2005,(2):18-20.
[52]荆双喜,张新红,冷军发.基于Labview的煤矿提升机故障诊断应用研究[J].煤矿机械,2005,(1):124-126.
[53]杨淑珍,徐文尚,高云红红.基于模糊推理的矿井提升机故障诊断方法的研究[J].煤矿机械,2005(9):148-150.
[54]刘志海,徐文尚,鲁青.矿井提升机故障诊断专家系统的研究[J].煤矿机械,2006,27(5):900-902.
[55]张华忠.基于无线传输的提升机钢丝绳张力动态检测与处理研究[D].青岛:山东科技大学,2006.
[56]孟令志,刘娟,王庆林.矿井提升机行程监控系统技术升级[J].煤矿现代化,2006,(S1):92-9.
[57]郝用兴.矿井提升机盘闸制动系统工作状态监控与安全[J].中国安全科学学报,2006,16(5):126-129.
[58]鲁青,徐文尚,刘志海等.基于FTA的矿井提升机钢丝绳断绳故障分析[J].煤矿机械,2006,27(2):356-358.
[59]胡国田,杨兆建.基于单片机的矿井提升机监测诊断系统设计[J].煤矿机械,2006,27(3):540-541.
[60]李曼.基于虚拟仪器技术和小波变换的钢丝绳断丝检测[J].起重运输机械,2006(4):79-81.
[61]卢文科,朱长纯,方建安等.小波变换用于钢丝绳断丝检测的研究[J].传感技术学报,2007,20(7):1659-1661.
[62]陈有兵.基于Intemt的提升机状态监测虚拟仪器技术研究[D].太原:太原理工大学,2008.
[63]滕孝来,肖兴明,胡明等.多绳摩擦提升钢丝绳张力动态无线监测[J].煤矿机械,2008,29(5):207-208.
[64]夏战国,张磊,牛强等.基于OPC的矿井提升机监测数据通信系统[J].数采与监测,2008,24(4):117-119.
[65]杨君.基于网络化虚拟仪器的矿井提升机监测系统设计与研究[D].昆明:昆明理-r-大学,2008.
[66]陈鑫.矿井提升机闸瓦间隙监控系统的研究[D].西安:西安科技大学,2008.
[67]黄友锐,唐超礼,黄见等.矿井提升机远程监控系统的设计与实现[J].煤炭工程,2008,8:13-14.
[68]朱胜利,王成勤,刘彦富.钢丝绳断丝在线监测系统的研制[J].煤矿机械.2009,30(3):133-135.
[69]周永华.钢丝绳故障的弱磁无损检测技术研究[D].武汉:武汉理工大学,2009.
[70]殷勇辉,范忠明,丁龙等.在线钢丝绳芯输送带实时扫描系统研究[J].煤矿机电,2009,4:39-41.
[71]刘建永.矿井提升机监控系统的分析与设计[D].北京:中国地质大学,2009.
[72]李飞仙.矿井提升钢丝绳监测装置研制及模拟分析[硕士学位论文][D].淮南:安徽理工大学,2010.
[73]何衍兴.金属矿山主提升设备安全监测与预警系统研究[硕士学位论文][D].武汉:中国地质大学大学,2010.
[74]冯刚.基于专家系统的矿井提升机制动系统的远程监测与诊断系统设计[硕士学位论文][D].成都:电子科技大学,2011.
[75]林乐刚.基于虚拟仪器的提升设备性能检测及故障诊断系统研究[硕士学位论文][D].邯郸:河北工程大学,2011.
[76]W.Gerald Wilbanks.50 Years of Progress in Measuring and Controlling Industrial Processes[J]. IEEE Control Systems Magazine, Feb.1996.
[77]A.P.Demin and GKh.Ismaiylov. Water Consumption and Drainage in the Volga Basin.Water Resources,2003,30(3):333-346.
[78]李瑞.井下排水系统的检测与控制研究[D].工学硕士学位论文,山西:太原理工大学,2006.
[79]高林.煤矿井下排水自动控制系统的研究与开发[硕士学位论文][D].太原:太原理工大学,2007.
[80]温国栋.基于ARM的煤矿自动排水监控系统的研究[D].工学硕士学位论文,陕西:西安科技大学,2009
[81]李杰.煤矿井下排水系统运行可靠性研究与控制系统研制[硕士学位论文][D].太原:太原理工大学,2010.
[82]李强.煤矿主排水监控系统的设计及应用[硕士学位论文][D].太原:太原理工大学,2010.
[83]朱本超.井下中央水泵房集中控制系统的设计与研究[硕士学位论文][D].沈阳:沈阳理工大学,2011.
[84]Kokai Yutaka,Masudu Furnio.Recent development in supervisory control system for EMS.Int J Power Energy Syst,1998.
[85]库德强.基于工控机和PLC的监控系统的研究[D],辽宁沈阳:沈阳工业大学,2006.
[86]刘新航.空气压缩机组监控系统开发[D]大连:大连理工大学,2006.
[87]王浩.空气压缩机集中监控系统的设计与实现[硕士学位论文][D].青岛:山东科技大学,2007.
[88]万毅.矿山空压机站智能监控系统的设计与实现[硕士学位论文][D].南京:南京理工大学,2007.
[89]叶凡.空压机在线监测诊断控制系统的研制[硕士学位论文][D].重庆:重庆大学,2008.
[90]李同运.空气压缩机组监控系统开发研究[硕士学位论文][D].太原:太原理工大学,2011.
[91]邱伟良.矿山关键设备安全运行集成监控系统设计[硕士学位论文][D].湘潭:湖南科技大学,2008.
[92]赵苍荣,周孟.基于ARM的CAN总线井下瓦斯监控系统[J].工矿自动化,2008(9):13-15.
[93]李飞龙,马玉芳.基于CAN总线的瓦斯监控系统[J].中国科技信息,2008(5):98-101.
[94]CHEN L,DU S F,WANG X Y.Design of data collection implement based on ARM9[J].Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument, 2006,27(n SUPPL):118-119.
[95]CHEN N,YU S L.LCD module interface designing and miniGUI implementing based on ARM[J]. Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument,2006,28(4):277-281+286.
[96]LU M S,YUE X B.The implementation of LCD high resolution application based on ARM9[C].20091st International Conference on Information Science and Engineering,2009.
[97]SUN Y B,XIE L,WANG Z L,et al.An embedded system of face recognition based on ARM and HMM[J].Lecture Notes in Computer Science, 2006(4740):389-394.
[98]TMS320DM642 Video/Imaging Fixed-Point Digital Signal Processor Data Manual,Literature Number.SPRS200B.Texas Instruments Inc orporated.2003.
[99]周霖.DSP信号处理技术应用[M].北京:国防工业出版社,2004.
[100]汪国有,赵蓝兰.采用DM642平台设计MPEG-4视频流传输系统[J].电视技术.2005.
[101]曾红.基于DSP及Web的分布式煤矿在线监测系统的设计[J].煤炭工程,2009(7):119-121.
[102]李磊.基于DSP和RS485总线的液压支架电液控制通信系统的设计[J].煤炭学报.2010(4):701-704.
[103]余雷声.电器控制与PLC应用[M].北京:机械工业出版社,1996(2):3-56.
[104]弭洪涛,可编程控制器(PLC)原理及应用[M].北京:中国水利出版社,1998(2):1-30.
[105]王为兵.PLC系统通信扩展与网络互连技术.北京:机械工业出版社,2005(1).
[106]苏中,李兴城.基于PC机架构的可编程控制器.北京:机械工业出版社,2005.
[107]孙同景,陈桂友.PLC原理及工程应用[M].北京:机械工业出版社,2008(7):22-170.
[108]蔡祥荣.RS485总线应用中的几个问题.力源电子工程.2001年,2月.15-17.
[109]韩红远,朱翔宇.CAN总线在煤矿安全监控系统中的应用[J].应用技术,2007(5):63-64.
[110]H.F.Othman,Y.R.Aji,FT.Fakhreddin,et al.Controller Area Networks:Evolution and Applications [C]. imformation and Communication Technologies,2006: ICTTA.2006:3088-3093.
[111]Nilufer.Cenesiz,Murat.Esin.Controller area network(CAN) for computer integrated manufacturing systems.Journal of Interlligent Manufacturing 2004(15):481-489.
[112]王跃东,杨卫波.CAN总线技术在煤矿监测系统中的应用研究[J].煤炭工程,2006(5):107-108.
[113]张丽,丁恩杰,何玉伟,彭瑞勇.矿用CAN/485总线网关的设计与实现[J].工矿自动化,2007(9):96-98.
[114]李伟忠.浅析光纤传输在矿井信息化建设中的作用[J].科技情报开发与经 济,2009(9):119-121.
[115]晏力,弹性分组环技术(RPR)[J].重庆工商大学学报(自然科学版),2003(12):56-59.
[116]徐海.主通风机在线监测系统的设计与应用[J].矿山机械,2007,35(11):38-40.
[117]JianLiu,Yan-chang Li and Qian-li Zhao.Study on unidirectional circuit problem in multi-fans-station ventilation type of Jinchuan No.2 mine.2008.7.
[118]夏俊生,王才.矿井主通风机在线监控系统[J].山东煤炭科技,2007,(5):43-44.
[119]刘晓明.矿井通风机监测系统[J].矿山机械,2006,34(12):29-31.
[120]陈蕊,基于PLC的矿井主扇风机的监控系统设计[D].太原:太原理工大学,2012.
[121]李占芳,郭磊,肖兴明.提升机系统性能测试及故障诊断.煤矿机械,2004(7),132-133.
[122]王振,李长青等.基C/S和B/S混合模式的矿井监控系统研究.工矿自动化,2008,第1期:70-72.
[123]李德臣,王峰.矿井提升机故障诊断技术研究.煤矿机电,2009,第五期:36-40.
[124]张秀平.矿井提升机监控系统的研究与实现.工矿自动化,2007.6.
[125]石缝.螺杆压缩机组运行状态在线监控系统研究[D].山东大学硕士学位论文,2009.
[126]钟凯,黄伟兵.螺杆式空气压缩机运行故障分析[J].广东化工.2008,35(182):144-145.
[127]付铁斌,王洪林.矿井主排水系统监测装置的研制[J].煤矿安全.2004.35(5):17-19.
[128]刘冰,陈洪亮.煤矿水泵自动化监控系统设计[J].煤矿机电.2004.7(5):100-102.
[129]孟宝堂,张建亮.高压自动闸阀设计设计实验与分析[J].流体机械.1998,26(9):6-8.
[130]顾颖诗.矿井通风机监控系统的设计与实现[D].成都:电子科技大学,2012.
[131]司颉.矿井主通风机在线监测与故障诊断系统研究[D].西安:西安科技大学,2012.
[132]李曼,司颉,张锋军.矿井主通风机在线监测与故障诊断系统[J].仪表技术与传感器,2013(1):62-63.
[133]袁泮泉.基于LabVIEW的矿井提升机运行状态监测与故障预警系统研究[D].邯郸:河北工程大学,2012.
[134]王栋.基于神经网络的矿井提升机监测与故障诊断系统的研究[D].青岛:山东科技大学,2006.
[135]孙宸.矿井自动化排水系统分析与研究[J].科技视界,2013(16):144-145.
[136]崔颖.煤矿井下排水自动控制系统的研究[D].阜新:辽宁工程技术大学,2010.
[137]郅富标.基于PLC的矿用空压机组综合保护系统研究[D].西安:西安科技大学,2009.
[138]苏记功.空气压缩机状态监测和故障诊断系统的研究[D].西安:西安建筑科技大学,2010.
[139]骆阳.矿山空气压缩机PLC控制系统[J].金属矿山,2008(12):142-144.
[140]牛群峰.压缩机智能状态监测理论与应用研究[D].南京:南京理工大学,2007.
[141]栾振辉,廖玲利.煤矿机械PLC控制技术[M].北京:化学工业出版社.2007.12.
[142]李民青,朱世松,赵建贵.煤矿安全生产和监控系统的现状与未来发展趋势[J].焦作工学院学报,2002(2):121-125.
[143]孙继平.矿井安全监控系统[M].北京:煤炭工业出版社,2006.
[144]中华人民共和国煤矿安全规程[S].北京:煤炭工业出版社,1992.
[145]王青维,龙大勇.串风甲烷传感器安设探讨[J].矿业安全与环保,2006(30):158-160.
[146]孙少军.浅谈矿井甲烷、一氧化碳和温度传感器的布置[J].铁法科技,2001(1):42-44.
[147]朱红青,等.煤矿井下输送带火灾传感器报警限和间距设计研究及应用[J].煤炭科学技术,2001,29(11):42-44.
[148]徐景德,周心权.煤矿胶带输送机火灾早期报警技术的研究[J].煤矿安全,1999(8):31-33.
[149][美]Vladimir N.Vapnik著;张学工译.统计学习理论的本质.清华大学出版社,2000.9
[150]Yamauchi,K.,Yamaguchi,N.,Ishii,N.Incremental learning methods with retrieving of interfered patterns. IEEE Transactions on Neural Networks,1999, 10(11):1351-1365.
[151][美]Nello Cristianini, John Shawe-Taylor著;李国正,王猛等译.支持向量机导论.电子工业出版社,2004.3
[152]Li Jianjun, Li Xibing, Zhang Shihua, Zhou Xianghong, Liu Junan. Gas Sensor of Working Face for Safety Monitoring based on SVM[J]. International Journal of Advancements in Computing Technology, Vol.5, No.7, April (2013):1042-1049
[153]李凯.传感器技术在机电一体化中的应用[J].科技向导,2011(06),77.
[154]韦雨.传感器在煤矿机电一体化中的运用与发展[J].科技资讯,2012(23),107.
[155]简小刚,贾鸿盛,石来德.多传感器信息融合技术的研究进展[J].中国工程机械学报,2009,7(2),227-232.
[156]何友,彭应宁,陆大金.多传感器数据融合模型评述[J].清华大学学报,1996,36(9):14-20.
[157]任彦.多传感器信息融合技术研究[D].哈尔滨:哈尔滨工程大学,2004.
[158]DASARATHY B V.Sensor fusion potential exploitation-innovative architectures and illustrative application[J]. Proc IEEE,1997,85(l):24-38.
[159]SOMMER K D,KUEHN O,LEON F P,et al.A bayesian approach to information fusion for evaluating the measurement uncertainty[J]. Robotics and Autonomous Systems,2009,57:339-344.
[160]王欣.多传感器数据融合问题的研究[D].长春:吉林大学,2006.
[161]BASIR O,YUAN Xiaohong.Engine fault diagnosis based on multi-sensor information fusion using dempster-shafer evidence theory [J].Information Fusion,2007(8):379-386.
[162]高青.多传感器数据融合算法研究[D].西安:西安电子科技大学,2008.
[163]陈津.传感器技术应用综述及发展趋势探讨[J].科技创新导报,2008(10):1.
[164]吴元忠,胡钢.基于ATmega128L的瓦斯检测报警装置的设计[J].工矿自动化,2007,(1):111-115.
[165]路秋英,郝国法,向晓东.基于51单片机和VB6.0的瓦斯浓度监测系统[J].工矿自动化,2008,(1):38.
[166]刘红霞,陈新.基于单片机的煤矿瓦斯小型智能监控系统设计[J].煤炭技术,2013,32(3):95-97.
[167]马正华,蒋建明,王正洪.基于CAN总线的ARM嵌入式瓦斯传感系统[J].煤炭科学技术,2007,35(1):114-117.
[168]田敏,崔建明.基于ARM的智能瓦斯监测系统研究[J].自动化与仪器仪表,2009,(5):23-27.
[169]唐密媛,张根宝.基于ARM Cortex-M3的便携式智能瓦检仪的设计[J].计算机测量与控制,2009,17(12):45-49.
[170]徐竟天.基于ARM9嵌入式和工业以太网的矿井瓦斯监控系统研究[D].西 安:西安科技大学,2011.
[171]付华,顾东,顾军等.基于ARM11的矿用智能便携式监控系统的研制[J].计算机测量与控制,2013.21(3):661-663.
[172]吴攀,吴永祥.基于DSP无线电台风井综合参数安全监控系统[J].煤炭科学技术,2006.10.
[173]姜飞.基于DSP的煤矿水源井无线监控系统的研究[D].淮南:安徽理工大学大学,2010.
[174]常勇.基于DSP的钻井监控系统研究[D].阜新:辽宁工程技术大学,2011.
[175]赫飞,张鹏,汪玉凤.基于PLC的煤矿井下排水系统的设计[J].冶金自动化,2008,S1:742-744.
[176]李顺,巨明伟.基于PLC的矿井排水监控系统的设计[J].工矿自动化,2011(10):89-91.
[177]宋阳.基于PLC矿井主排水自动控制系统的设计[J].制造业自动化.2012,34(9):120-123.
[178]杜晓坤.信息融合与LonWorks总线在煤矿监测系统中的应用研究[D].阜新:辽宁工程技术大学,2005.
[179]杨公平,朱方金.基于485总线分布式监控系统的研究与实现[J].微机发展,2003,13(7):75-76.
[180]秦薇薇,丁恩杰,李娜.基于RS-485总线的井下变电所监控系统设计[C].//第十四届全国煤矿自动化学术年会暨中国煤炭学会自动化专业委员会学术会议论文集,中国煤炭学会,2004:63-66.
[181]赵小兵,周雪峰.煤矿安全监控系统中RS485总线的抗干扰设计[J].工矿自动化,2013,39(2):83-86.
[182]张海涛,李威.王贤峰,苑云峰.基于Profibus-DP,总线矿井压风机监控系统设计[J].矿山机械,2008,36(17):14-16.
[183]张涛.基于Profibus-DP总线的煤矿安全生产监测监控系统[C].//张铁岗、曲凯.第三届全国煤矿机械安全装备技术发展高层论坛暨新产品技术交流会论文集,中国煤炭机械工业协会,2012:463-469.
[184]杜鸿等.CAN总线在矿井火灾监控系统中的应用[J].煤矿安全,2000(10):38-40.
[185]张荣才等.基于CAN总线的煤矿地磅房监控系统[J].工矿自动化,2003(6):46-48.
[186]严辉,夏巍,丁刚.基于CAN总线的煤矿瓦斯报警系统的设计[J].工业仪表与自动化装置,2007(4):33-35.
[187]廖平,谢乐添,魏树伟.基于CAN总线的煤矿井下风机监控系统实现[J].现代电子技术,2007,(7):177-180.
[188]赵冬青.基于CAN总线的煤矿安全监测系统研究[D].中北大学硕士论文,2008.
[189]唐良义,高嵩,杨水林,刘志海,罗毅翔.煤矿风机运转状态监测与自动控制[J].自动化技术与应用,2010,29(4):27-29.煤矿风机智能化监控系统
[190]韩芳,朱玉琴.煤矿风机智能化监控系统[J].煤矿机械,2009,30(2):142-144.
[191]韩芳,朱玉琴.基于CAN总线的煤矿风机监控系统设计[J].微计算机信息,2009,25(6-2):111-112.
[192]韩芳,朱玉琴.煤矿风机监控系统中CAN总线网络的建模和仿真[J].科技信息,2012,(7):65-37.
[193]韩英杰.交换式以太网在矿井监控系统中的应用[J].中国安全生产科学技术,2006,2(2):89-91.
[194]钱建生,李鹏,顾军等.基于防爆工业以太网的煤矿综合自动化系统[J].中国煤炭,2006(3):20-21.
[195]范高贤,周波,殷庆平.光纤工业以太环网在煤矿安全监控系统中的应用[J].工矿自动化,2007(6):108-110.
[196]徐竟天,李树刚,黄金星.基于工业以太网的矿井瓦斯井下监控分站研究[C].中国通信学会学术年会论文集ISTP卷,2010.3.
[197]李树刚,徐竟天,黄金星.基于工业以太网的瓦斯监控系统设计[J]中国安全生产科学技术,2010,6(2):141-145.
[198]伍龙,吴永祥,邢丽坤.基于以太网的嵌入式煤矿井下电力安全监控系统研究[J].煤炭工程,2010(12):16-18.
[199]万国峰,曹永春.基于GPRS的无线煤矿监测监控系统设计[J].信息科技,2007(19):114-115.
[200]尹盼.基于ZigBee技术的矿井综合监测系统设计与网络节点开发[D].长沙:中南大学,2009.
[201]覃磊,张杰.基于ZigBee技术的煤矿瓦斯监测系统[J].计量与测试技术,2007,34(1):111-115.
[202]湛浩星,孙长篙,吴珊等.ZigBee技术在煤矿井下救援系统中的应用[J].工程与应用,2006:12-14.
[203]金纯,齐岩松,罗祖秋.ZigBee在矿井安全领域的应用[J].煤矿安全,2006(2),39-41.
[204]葛晓宇,王庆辉,魏立峰.ZigBee技术及其在矿山中的应用[J].微计算机信 息,2007:44-45.
[205]沈力,基于无线通信的矿井监控系统的优化设计研究[D].重庆:重庆大学,2012.
[206]孟庆仁.光纤技术在采矿工业中的应用及其发展[J].国外金属矿山,1993(6):76-84.
[207]LIU T Y.All fiber optic coal mine safety monitoring system [C].2007 Asia Optical Fiber Communication and Optoelectronic Exposition and Conference, AOE,2007.
[208]龙志强,李迅,李晓龙等.现场总线控制网络技术[M].北京:机械工业出版社,2011.
[209]刘明启.基于Visual C++的矿井监控组态软件的研究与设计[J].煤炭技术,2012,31(12):88-90.
[210]王永红.基于InTouch的煤矿井下电力监控系统的设计与研究[D].太原:太原理工大学,2012.
[211]袁佩丽.基于LabVIEW的矿井水文监控系统研究[D].长沙:中南大学,2012.
[212]胡嘉坤,陆绮荣.基于LabVIEW的矿井瓦斯远程监控系统[J].7-矿自动化,2007,(2):64-66.
[213]汤青波,何学文.基于LABVIEW的风机在线监测系统开发[J].噪声与振动控制,2007,(2):47-48.
[214]徐春艳,华钢,刘晓东,胡义华.基于MCGS组态软件的煤矿监控系统的研究[J].工矿自动化,2005(5):28-30.
[215]叶磊.基于力控组态软件的压力机监控系统[D].南宁,广西大学,2008.
[216]刘璐,基于PLC及组态王的煤矿地面生产控制系统研究[D].淮南:安徽理工大学,2011.
[217]沙宝银,刘雨刚,杨春孝.基于组态王6.5的矿井通风主扇监控系统[J].辽宁工程技术大学学报,2005,24(s1):158-160.
[218]严桂,贾存良,黄文芳.基于CAN总线与组态王的瓦斯监控系统[J].仪表技术与传感器,2008(5):52-54.
[219]李兆坤.基于CAN总线与组态王的粮库监控系统的研究[D].成都:西南石油大学,2007.
[2]Mutmansky J M,Wang A.Patterns of methane emission and their effects on mining costs in underground mining operations [J].Mihing Engineering, 1999,51(1):65-70.
[3]Brake D J,Rick D.Fan total pressure or fanstatic pressure:Which is correct when solving ventilation Problems[J].Mine ventilation Society of South Africa 2002,55(1):6-11.
[4]Lin Y X,Ma F Q,Cang X J.Three layer model for digital coal mine based on industrial ethernet[J].Collection of information and eleetrical engineering, 2008,30(2):1710-1714.
[5]Raina A,Ramulu M.Application of digital image analysis technique for assessment of blast fragmentation and explosives energy ultlisation in a large opencost coal mine[J].Transportation Research Board of the National Academics,2008,56(7):140-147.
[6]Zhang L,Xu Z,Yuan W C.Study on key technologies of digital mine integrated transmission Platform[C],ICIA2007:75-78.
[7]Trutwin W.Use of digital computers for the study of non-Steady states and automatic control problems in mine ventilation networks[J].International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 1972,9(2):289-323.
[8]孙英,近十年我国金属矿山通风系统的技术改造[J].金属矿山,1994,12(5):25-29.
[9]韩慧.矿井通风安全自动监测报警系统[D].青岛:山东科技大学,1999.
[10]海伦.煤矿信息化:信息产业新增长点[J].中国电子报,2005,23(4):34-36.
[11]李继培.煤矿井下灾害调查与研究[J].中国安全生产科学研究报,2005,24(7):23-25.
[12]冯晓芳.我国力推信息技术在煤矿安全领域应用[N].新华社北京,2005.10.03.
[13]米建国,李继培.依靠科技遏制瓦斯矿难[N].国务院发展研究中心信息中心,2005.08.02.
[14]Chen J Y,Zhang S,Zuo W R.Digital Coal Mine Integrated Automation System based on Controlnet[J]. Journal of China university of mining & technology, 2007,17(2):210-214.
[15]易志根.矿井通风监控系统设计与开发[硕士学位论文][D].长沙:中南大学,2010
[16]Wang Y J. Characteristics of multiple fan ventilation networks [J]. International journal of mining engineering,1984,12(2):229-243.
[17]Enb L M,Wang Y J.Characteristic curves revisited:a more logical approach to determining operating points [C], Mining Engineering (Lilttleton,Colorado), 1998:65-69.
[18]Wang Q F,Zhang X H.The digitization-emulation optimization and forecasting of mine ventilation system [J].Epic Consulting Services Ltd,2002, 12(6):480-484.
[19]Hardy C.The Influence of Mathematics on the Development of structural Form.Institute for Structural Design II,Germany,1935,23(4):212-221.
[20]赵梓成,谢贤平.矿井通风理论与技术进展评述[J].云南冶金,2002,31(3):24-31.
[21]Fu H,Shao L S.An optimized control of ventilation in coal mines based on artificial neual network. Journal of coal science & Engineering,2002, 8(2):80-83.
[22]Stefanko H,Baran A.Digital computer-based vibration monitoring in underground coal mine equipment [J].Senior Member of IEEE American Electric Powr 1988,35(6):1250-1254.
[23]Rastogi,Ven K.Digital control systems for mines and industrial Processes[J].Measurement Techniques,1984,1(2):21-28.
[24]沈斐敏.矿井通风系统合理性的综合评判[C].第二次全国采矿学术会议论文集(汇),1956(11):253-294.
[25]杨运良.矿井通风系统网路结构复杂程度的评价[J].煤矿安全,1998,29(1):321-334.
[26]李恕如,王义章.矿井通风网络图论[M].北京:煤炭工业出版社,1984:48-60,86-90.
[27]张惠忱.计算机在矿井通风中的应用[M].徐州:中国矿业大学出版,1992:62-234.
[28]赵以蕙.通风网络理论[M].北京:煤炭工业出版社,1993:66-81,161-179.
[29]王建浩,李承凯.管网故障微机诊断的实用方法[J].控制与测量,1999(2): 45-49.
[30]Le Gat Yves,Eisenbeis Patrick.Using maintenance records to forecast failures in water networks [J]. UrbanWater,2000,2(3):173-181.
[31]D.N.Shields,S.A.Ashton,S.Daley.Design of nonlinear observers for detecting faults in hydraulic sub-sea pipelines[J]. Control Engineering Praetice, 2001(9):297-311.
[32]梁建文,肖笛等.水管网故障实时诊断方法[J].水利学报,2001(12):40-47.
[33]税爱社,周绍骑.输油管线泄漏诊断的SCADA系统实现[D].仪器仪表学报,2001,22(4):229-230.
[34]龚晓燕,薛河,陶新利,孙晓辉.矿井局部通风故障诊断系统开发研究[J].煤炭工程,2008(2):128-130.
[35]黄雷.基于Web的矿井局部通风故障诊断专家系统[D].西安科技大学,2008:6-8.
[36]龚晓燕,孙晓辉.基于遗传算法的矿井局部通风故障诊断神经网络模型[J].煤矿安全,2008(2):35-38.
[37]赵丹.基于网络分析的矿井通风系统故障源诊断技术研究[博士学位论文][D].阜新:辽宁工程技术大学,2011.
[38]裴九芳.基于LabVIEW的矿井提升机监控系统[D].合肥:安徽理工大学,2005.
[39]荆双喜,赵玉峰,王建生.用噪声对提升机减速箱进行故障诊断[J].煤矿机械,1994,(3):27-29.
[40]肖兴明,黄小军,马小平等.矿井提升机监护系统的实现[J].仪表技术与传感器,1999(9):23-25.
[41]梁兆正,李文宏,肖林京,等.矿井提升机状态监测与故障诊断系统[J].矿山机械,1999,(3):38-41.
[42]张秀平.矿井提升机监测系统的研究与实现[J].工矿自动化,1999(1):23-24.
[43]付华,杨宝霖,高迎惠.基于多传感器信息融合的矿井提升机监测系统[J].辽宁工程技术大学学报(自然科学版),2001,20(1):60-62.
[44]黄民,李功,张永忠.矿井提升机振动测试与故障诊断[J].煤矿机械,2002(12):79-81.
[45]夏本春,周金荣,李至斌.提升机减速箱故障预报的实践[J].煤炭科技,2002,(1):36-37.
[46]刘可伟,杨兆建.基于人工神经网络的提升设备故障诊断研究[J].太原理工大学学报,2002,33(4):441-443.
[47]刘金琪,吕瑞丰.基于无线数据传输的钢丝绳张力监测系统[J].控制工程,2003,25(4):402-405.
[48]陈洁,杨兆建,高强.基于ANNES的矿井提升机故障诊断系统模型[J].机械管理开发,2004,77(2):14-15.
[49]王增才,聂志峰,邵海燕.多绳提升钢丝绳动态张力监测研究[J].仪器仪表学报,2004,10(3):364-372.
[50]王致杰,王崇林,卢文海等.煤矿提升机综合安全智能控制策略研究[C].第十五届全国煤矿自动化学术年会和中国煤炭学会煤矿自动化专业委员会学术会议论文集.第十五届全国煤矿自动化学术年会和中国煤炭学会煤矿自动化专业委员会学术会议.昆明:中国煤炭学会煤矿自动化专业委员会,2005.
[51]赵廷钊.提升机减速箱故障诊断技术研究[J].煤矿机电,2005,(2):18-20.
[52]荆双喜,张新红,冷军发.基于Labview的煤矿提升机故障诊断应用研究[J].煤矿机械,2005,(1):124-126.
[53]杨淑珍,徐文尚,高云红红.基于模糊推理的矿井提升机故障诊断方法的研究[J].煤矿机械,2005(9):148-150.
[54]刘志海,徐文尚,鲁青.矿井提升机故障诊断专家系统的研究[J].煤矿机械,2006,27(5):900-902.
[55]张华忠.基于无线传输的提升机钢丝绳张力动态检测与处理研究[D].青岛:山东科技大学,2006.
[56]孟令志,刘娟,王庆林.矿井提升机行程监控系统技术升级[J].煤矿现代化,2006,(S1):92-9.
[57]郝用兴.矿井提升机盘闸制动系统工作状态监控与安全[J].中国安全科学学报,2006,16(5):126-129.
[58]鲁青,徐文尚,刘志海等.基于FTA的矿井提升机钢丝绳断绳故障分析[J].煤矿机械,2006,27(2):356-358.
[59]胡国田,杨兆建.基于单片机的矿井提升机监测诊断系统设计[J].煤矿机械,2006,27(3):540-541.
[60]李曼.基于虚拟仪器技术和小波变换的钢丝绳断丝检测[J].起重运输机械,2006(4):79-81.
[61]卢文科,朱长纯,方建安等.小波变换用于钢丝绳断丝检测的研究[J].传感技术学报,2007,20(7):1659-1661.
[62]陈有兵.基于Intemt的提升机状态监测虚拟仪器技术研究[D].太原:太原理工大学,2008.
[63]滕孝来,肖兴明,胡明等.多绳摩擦提升钢丝绳张力动态无线监测[J].煤矿机械,2008,29(5):207-208.
[64]夏战国,张磊,牛强等.基于OPC的矿井提升机监测数据通信系统[J].数采与监测,2008,24(4):117-119.
[65]杨君.基于网络化虚拟仪器的矿井提升机监测系统设计与研究[D].昆明:昆明理-r-大学,2008.
[66]陈鑫.矿井提升机闸瓦间隙监控系统的研究[D].西安:西安科技大学,2008.
[67]黄友锐,唐超礼,黄见等.矿井提升机远程监控系统的设计与实现[J].煤炭工程,2008,8:13-14.
[68]朱胜利,王成勤,刘彦富.钢丝绳断丝在线监测系统的研制[J].煤矿机械.2009,30(3):133-135.
[69]周永华.钢丝绳故障的弱磁无损检测技术研究[D].武汉:武汉理工大学,2009.
[70]殷勇辉,范忠明,丁龙等.在线钢丝绳芯输送带实时扫描系统研究[J].煤矿机电,2009,4:39-41.
[71]刘建永.矿井提升机监控系统的分析与设计[D].北京:中国地质大学,2009.
[72]李飞仙.矿井提升钢丝绳监测装置研制及模拟分析[硕士学位论文][D].淮南:安徽理工大学,2010.
[73]何衍兴.金属矿山主提升设备安全监测与预警系统研究[硕士学位论文][D].武汉:中国地质大学大学,2010.
[74]冯刚.基于专家系统的矿井提升机制动系统的远程监测与诊断系统设计[硕士学位论文][D].成都:电子科技大学,2011.
[75]林乐刚.基于虚拟仪器的提升设备性能检测及故障诊断系统研究[硕士学位论文][D].邯郸:河北工程大学,2011.
[76]W.Gerald Wilbanks.50 Years of Progress in Measuring and Controlling Industrial Processes[J]. IEEE Control Systems Magazine, Feb.1996.
[77]A.P.Demin and GKh.Ismaiylov. Water Consumption and Drainage in the Volga Basin.Water Resources,2003,30(3):333-346.
[78]李瑞.井下排水系统的检测与控制研究[D].工学硕士学位论文,山西:太原理工大学,2006.
[79]高林.煤矿井下排水自动控制系统的研究与开发[硕士学位论文][D].太原:太原理工大学,2007.
[80]温国栋.基于ARM的煤矿自动排水监控系统的研究[D].工学硕士学位论文,陕西:西安科技大学,2009
[81]李杰.煤矿井下排水系统运行可靠性研究与控制系统研制[硕士学位论文][D].太原:太原理工大学,2010.
[82]李强.煤矿主排水监控系统的设计及应用[硕士学位论文][D].太原:太原理工大学,2010.
[83]朱本超.井下中央水泵房集中控制系统的设计与研究[硕士学位论文][D].沈阳:沈阳理工大学,2011.
[84]Kokai Yutaka,Masudu Furnio.Recent development in supervisory control system for EMS.Int J Power Energy Syst,1998.
[85]库德强.基于工控机和PLC的监控系统的研究[D],辽宁沈阳:沈阳工业大学,2006.
[86]刘新航.空气压缩机组监控系统开发[D]大连:大连理工大学,2006.
[87]王浩.空气压缩机集中监控系统的设计与实现[硕士学位论文][D].青岛:山东科技大学,2007.
[88]万毅.矿山空压机站智能监控系统的设计与实现[硕士学位论文][D].南京:南京理工大学,2007.
[89]叶凡.空压机在线监测诊断控制系统的研制[硕士学位论文][D].重庆:重庆大学,2008.
[90]李同运.空气压缩机组监控系统开发研究[硕士学位论文][D].太原:太原理工大学,2011.
[91]邱伟良.矿山关键设备安全运行集成监控系统设计[硕士学位论文][D].湘潭:湖南科技大学,2008.
[92]赵苍荣,周孟.基于ARM的CAN总线井下瓦斯监控系统[J].工矿自动化,2008(9):13-15.
[93]李飞龙,马玉芳.基于CAN总线的瓦斯监控系统[J].中国科技信息,2008(5):98-101.
[94]CHEN L,DU S F,WANG X Y.Design of data collection implement based on ARM9[J].Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument, 2006,27(n SUPPL):118-119.
[95]CHEN N,YU S L.LCD module interface designing and miniGUI implementing based on ARM[J]. Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument,2006,28(4):277-281+286.
[96]LU M S,YUE X B.The implementation of LCD high resolution application based on ARM9[C].20091st International Conference on Information Science and Engineering,2009.
[97]SUN Y B,XIE L,WANG Z L,et al.An embedded system of face recognition based on ARM and HMM[J].Lecture Notes in Computer Science, 2006(4740):389-394.
[98]TMS320DM642 Video/Imaging Fixed-Point Digital Signal Processor Data Manual,Literature Number.SPRS200B.Texas Instruments Inc orporated.2003.
[99]周霖.DSP信号处理技术应用[M].北京:国防工业出版社,2004.
[100]汪国有,赵蓝兰.采用DM642平台设计MPEG-4视频流传输系统[J].电视技术.2005.
[101]曾红.基于DSP及Web的分布式煤矿在线监测系统的设计[J].煤炭工程,2009(7):119-121.
[102]李磊.基于DSP和RS485总线的液压支架电液控制通信系统的设计[J].煤炭学报.2010(4):701-704.
[103]余雷声.电器控制与PLC应用[M].北京:机械工业出版社,1996(2):3-56.
[104]弭洪涛,可编程控制器(PLC)原理及应用[M].北京:中国水利出版社,1998(2):1-30.
[105]王为兵.PLC系统通信扩展与网络互连技术.北京:机械工业出版社,2005(1).
[106]苏中,李兴城.基于PC机架构的可编程控制器.北京:机械工业出版社,2005.
[107]孙同景,陈桂友.PLC原理及工程应用[M].北京:机械工业出版社,2008(7):22-170.
[108]蔡祥荣.RS485总线应用中的几个问题.力源电子工程.2001年,2月.15-17.
[109]韩红远,朱翔宇.CAN总线在煤矿安全监控系统中的应用[J].应用技术,2007(5):63-64.
[110]H.F.Othman,Y.R.Aji,FT.Fakhreddin,et al.Controller Area Networks:Evolution and Applications [C]. imformation and Communication Technologies,2006: ICTTA.2006:3088-3093.
[111]Nilufer.Cenesiz,Murat.Esin.Controller area network(CAN) for computer integrated manufacturing systems.Journal of Interlligent Manufacturing 2004(15):481-489.
[112]王跃东,杨卫波.CAN总线技术在煤矿监测系统中的应用研究[J].煤炭工程,2006(5):107-108.
[113]张丽,丁恩杰,何玉伟,彭瑞勇.矿用CAN/485总线网关的设计与实现[J].工矿自动化,2007(9):96-98.
[114]李伟忠.浅析光纤传输在矿井信息化建设中的作用[J].科技情报开发与经 济,2009(9):119-121.
[115]晏力,弹性分组环技术(RPR)[J].重庆工商大学学报(自然科学版),2003(12):56-59.
[116]徐海.主通风机在线监测系统的设计与应用[J].矿山机械,2007,35(11):38-40.
[117]JianLiu,Yan-chang Li and Qian-li Zhao.Study on unidirectional circuit problem in multi-fans-station ventilation type of Jinchuan No.2 mine.2008.7.
[118]夏俊生,王才.矿井主通风机在线监控系统[J].山东煤炭科技,2007,(5):43-44.
[119]刘晓明.矿井通风机监测系统[J].矿山机械,2006,34(12):29-31.
[120]陈蕊,基于PLC的矿井主扇风机的监控系统设计[D].太原:太原理工大学,2012.
[121]李占芳,郭磊,肖兴明.提升机系统性能测试及故障诊断.煤矿机械,2004(7),132-133.
[122]王振,李长青等.基C/S和B/S混合模式的矿井监控系统研究.工矿自动化,2008,第1期:70-72.
[123]李德臣,王峰.矿井提升机故障诊断技术研究.煤矿机电,2009,第五期:36-40.
[124]张秀平.矿井提升机监控系统的研究与实现.工矿自动化,2007.6.
[125]石缝.螺杆压缩机组运行状态在线监控系统研究[D].山东大学硕士学位论文,2009.
[126]钟凯,黄伟兵.螺杆式空气压缩机运行故障分析[J].广东化工.2008,35(182):144-145.
[127]付铁斌,王洪林.矿井主排水系统监测装置的研制[J].煤矿安全.2004.35(5):17-19.
[128]刘冰,陈洪亮.煤矿水泵自动化监控系统设计[J].煤矿机电.2004.7(5):100-102.
[129]孟宝堂,张建亮.高压自动闸阀设计设计实验与分析[J].流体机械.1998,26(9):6-8.
[130]顾颖诗.矿井通风机监控系统的设计与实现[D].成都:电子科技大学,2012.
[131]司颉.矿井主通风机在线监测与故障诊断系统研究[D].西安:西安科技大学,2012.
[132]李曼,司颉,张锋军.矿井主通风机在线监测与故障诊断系统[J].仪表技术与传感器,2013(1):62-63.
[133]袁泮泉.基于LabVIEW的矿井提升机运行状态监测与故障预警系统研究[D].邯郸:河北工程大学,2012.
[134]王栋.基于神经网络的矿井提升机监测与故障诊断系统的研究[D].青岛:山东科技大学,2006.
[135]孙宸.矿井自动化排水系统分析与研究[J].科技视界,2013(16):144-145.
[136]崔颖.煤矿井下排水自动控制系统的研究[D].阜新:辽宁工程技术大学,2010.
[137]郅富标.基于PLC的矿用空压机组综合保护系统研究[D].西安:西安科技大学,2009.
[138]苏记功.空气压缩机状态监测和故障诊断系统的研究[D].西安:西安建筑科技大学,2010.
[139]骆阳.矿山空气压缩机PLC控制系统[J].金属矿山,2008(12):142-144.
[140]牛群峰.压缩机智能状态监测理论与应用研究[D].南京:南京理工大学,2007.
[141]栾振辉,廖玲利.煤矿机械PLC控制技术[M].北京:化学工业出版社.2007.12.
[142]李民青,朱世松,赵建贵.煤矿安全生产和监控系统的现状与未来发展趋势[J].焦作工学院学报,2002(2):121-125.
[143]孙继平.矿井安全监控系统[M].北京:煤炭工业出版社,2006.
[144]中华人民共和国煤矿安全规程[S].北京:煤炭工业出版社,1992.
[145]王青维,龙大勇.串风甲烷传感器安设探讨[J].矿业安全与环保,2006(30):158-160.
[146]孙少军.浅谈矿井甲烷、一氧化碳和温度传感器的布置[J].铁法科技,2001(1):42-44.
[147]朱红青,等.煤矿井下输送带火灾传感器报警限和间距设计研究及应用[J].煤炭科学技术,2001,29(11):42-44.
[148]徐景德,周心权.煤矿胶带输送机火灾早期报警技术的研究[J].煤矿安全,1999(8):31-33.
[149][美]Vladimir N.Vapnik著;张学工译.统计学习理论的本质.清华大学出版社,2000.9
[150]Yamauchi,K.,Yamaguchi,N.,Ishii,N.Incremental learning methods with retrieving of interfered patterns. IEEE Transactions on Neural Networks,1999, 10(11):1351-1365.
[151][美]Nello Cristianini, John Shawe-Taylor著;李国正,王猛等译.支持向量机导论.电子工业出版社,2004.3
[152]Li Jianjun, Li Xibing, Zhang Shihua, Zhou Xianghong, Liu Junan. Gas Sensor of Working Face for Safety Monitoring based on SVM[J]. International Journal of Advancements in Computing Technology, Vol.5, No.7, April (2013):1042-1049
[153]李凯.传感器技术在机电一体化中的应用[J].科技向导,2011(06),77.
[154]韦雨.传感器在煤矿机电一体化中的运用与发展[J].科技资讯,2012(23),107.
[155]简小刚,贾鸿盛,石来德.多传感器信息融合技术的研究进展[J].中国工程机械学报,2009,7(2),227-232.
[156]何友,彭应宁,陆大金.多传感器数据融合模型评述[J].清华大学学报,1996,36(9):14-20.
[157]任彦.多传感器信息融合技术研究[D].哈尔滨:哈尔滨工程大学,2004.
[158]DASARATHY B V.Sensor fusion potential exploitation-innovative architectures and illustrative application[J]. Proc IEEE,1997,85(l):24-38.
[159]SOMMER K D,KUEHN O,LEON F P,et al.A bayesian approach to information fusion for evaluating the measurement uncertainty[J]. Robotics and Autonomous Systems,2009,57:339-344.
[160]王欣.多传感器数据融合问题的研究[D].长春:吉林大学,2006.
[161]BASIR O,YUAN Xiaohong.Engine fault diagnosis based on multi-sensor information fusion using dempster-shafer evidence theory [J].Information Fusion,2007(8):379-386.
[162]高青.多传感器数据融合算法研究[D].西安:西安电子科技大学,2008.
[163]陈津.传感器技术应用综述及发展趋势探讨[J].科技创新导报,2008(10):1.
[164]吴元忠,胡钢.基于ATmega128L的瓦斯检测报警装置的设计[J].工矿自动化,2007,(1):111-115.
[165]路秋英,郝国法,向晓东.基于51单片机和VB6.0的瓦斯浓度监测系统[J].工矿自动化,2008,(1):38.
[166]刘红霞,陈新.基于单片机的煤矿瓦斯小型智能监控系统设计[J].煤炭技术,2013,32(3):95-97.
[167]马正华,蒋建明,王正洪.基于CAN总线的ARM嵌入式瓦斯传感系统[J].煤炭科学技术,2007,35(1):114-117.
[168]田敏,崔建明.基于ARM的智能瓦斯监测系统研究[J].自动化与仪器仪表,2009,(5):23-27.
[169]唐密媛,张根宝.基于ARM Cortex-M3的便携式智能瓦检仪的设计[J].计算机测量与控制,2009,17(12):45-49.
[170]徐竟天.基于ARM9嵌入式和工业以太网的矿井瓦斯监控系统研究[D].西 安:西安科技大学,2011.
[171]付华,顾东,顾军等.基于ARM11的矿用智能便携式监控系统的研制[J].计算机测量与控制,2013.21(3):661-663.
[172]吴攀,吴永祥.基于DSP无线电台风井综合参数安全监控系统[J].煤炭科学技术,2006.10.
[173]姜飞.基于DSP的煤矿水源井无线监控系统的研究[D].淮南:安徽理工大学大学,2010.
[174]常勇.基于DSP的钻井监控系统研究[D].阜新:辽宁工程技术大学,2011.
[175]赫飞,张鹏,汪玉凤.基于PLC的煤矿井下排水系统的设计[J].冶金自动化,2008,S1:742-744.
[176]李顺,巨明伟.基于PLC的矿井排水监控系统的设计[J].工矿自动化,2011(10):89-91.
[177]宋阳.基于PLC矿井主排水自动控制系统的设计[J].制造业自动化.2012,34(9):120-123.
[178]杜晓坤.信息融合与LonWorks总线在煤矿监测系统中的应用研究[D].阜新:辽宁工程技术大学,2005.
[179]杨公平,朱方金.基于485总线分布式监控系统的研究与实现[J].微机发展,2003,13(7):75-76.
[180]秦薇薇,丁恩杰,李娜.基于RS-485总线的井下变电所监控系统设计[C].//第十四届全国煤矿自动化学术年会暨中国煤炭学会自动化专业委员会学术会议论文集,中国煤炭学会,2004:63-66.
[181]赵小兵,周雪峰.煤矿安全监控系统中RS485总线的抗干扰设计[J].工矿自动化,2013,39(2):83-86.
[182]张海涛,李威.王贤峰,苑云峰.基于Profibus-DP,总线矿井压风机监控系统设计[J].矿山机械,2008,36(17):14-16.
[183]张涛.基于Profibus-DP总线的煤矿安全生产监测监控系统[C].//张铁岗、曲凯.第三届全国煤矿机械安全装备技术发展高层论坛暨新产品技术交流会论文集,中国煤炭机械工业协会,2012:463-469.
[184]杜鸿等.CAN总线在矿井火灾监控系统中的应用[J].煤矿安全,2000(10):38-40.
[185]张荣才等.基于CAN总线的煤矿地磅房监控系统[J].工矿自动化,2003(6):46-48.
[186]严辉,夏巍,丁刚.基于CAN总线的煤矿瓦斯报警系统的设计[J].工业仪表与自动化装置,2007(4):33-35.
[187]廖平,谢乐添,魏树伟.基于CAN总线的煤矿井下风机监控系统实现[J].现代电子技术,2007,(7):177-180.
[188]赵冬青.基于CAN总线的煤矿安全监测系统研究[D].中北大学硕士论文,2008.
[189]唐良义,高嵩,杨水林,刘志海,罗毅翔.煤矿风机运转状态监测与自动控制[J].自动化技术与应用,2010,29(4):27-29.煤矿风机智能化监控系统
[190]韩芳,朱玉琴.煤矿风机智能化监控系统[J].煤矿机械,2009,30(2):142-144.
[191]韩芳,朱玉琴.基于CAN总线的煤矿风机监控系统设计[J].微计算机信息,2009,25(6-2):111-112.
[192]韩芳,朱玉琴.煤矿风机监控系统中CAN总线网络的建模和仿真[J].科技信息,2012,(7):65-37.
[193]韩英杰.交换式以太网在矿井监控系统中的应用[J].中国安全生产科学技术,2006,2(2):89-91.
[194]钱建生,李鹏,顾军等.基于防爆工业以太网的煤矿综合自动化系统[J].中国煤炭,2006(3):20-21.
[195]范高贤,周波,殷庆平.光纤工业以太环网在煤矿安全监控系统中的应用[J].工矿自动化,2007(6):108-110.
[196]徐竟天,李树刚,黄金星.基于工业以太网的矿井瓦斯井下监控分站研究[C].中国通信学会学术年会论文集ISTP卷,2010.3.
[197]李树刚,徐竟天,黄金星.基于工业以太网的瓦斯监控系统设计[J]中国安全生产科学技术,2010,6(2):141-145.
[198]伍龙,吴永祥,邢丽坤.基于以太网的嵌入式煤矿井下电力安全监控系统研究[J].煤炭工程,2010(12):16-18.
[199]万国峰,曹永春.基于GPRS的无线煤矿监测监控系统设计[J].信息科技,2007(19):114-115.
[200]尹盼.基于ZigBee技术的矿井综合监测系统设计与网络节点开发[D].长沙:中南大学,2009.
[201]覃磊,张杰.基于ZigBee技术的煤矿瓦斯监测系统[J].计量与测试技术,2007,34(1):111-115.
[202]湛浩星,孙长篙,吴珊等.ZigBee技术在煤矿井下救援系统中的应用[J].工程与应用,2006:12-14.
[203]金纯,齐岩松,罗祖秋.ZigBee在矿井安全领域的应用[J].煤矿安全,2006(2),39-41.
[204]葛晓宇,王庆辉,魏立峰.ZigBee技术及其在矿山中的应用[J].微计算机信 息,2007:44-45.
[205]沈力,基于无线通信的矿井监控系统的优化设计研究[D].重庆:重庆大学,2012.
[206]孟庆仁.光纤技术在采矿工业中的应用及其发展[J].国外金属矿山,1993(6):76-84.
[207]LIU T Y.All fiber optic coal mine safety monitoring system [C].2007 Asia Optical Fiber Communication and Optoelectronic Exposition and Conference, AOE,2007.
[208]龙志强,李迅,李晓龙等.现场总线控制网络技术[M].北京:机械工业出版社,2011.
[209]刘明启.基于Visual C++的矿井监控组态软件的研究与设计[J].煤炭技术,2012,31(12):88-90.
[210]王永红.基于InTouch的煤矿井下电力监控系统的设计与研究[D].太原:太原理工大学,2012.
[211]袁佩丽.基于LabVIEW的矿井水文监控系统研究[D].长沙:中南大学,2012.
[212]胡嘉坤,陆绮荣.基于LabVIEW的矿井瓦斯远程监控系统[J].7-矿自动化,2007,(2):64-66.
[213]汤青波,何学文.基于LABVIEW的风机在线监测系统开发[J].噪声与振动控制,2007,(2):47-48.
[214]徐春艳,华钢,刘晓东,胡义华.基于MCGS组态软件的煤矿监控系统的研究[J].工矿自动化,2005(5):28-30.
[215]叶磊.基于力控组态软件的压力机监控系统[D].南宁,广西大学,2008.
[216]刘璐,基于PLC及组态王的煤矿地面生产控制系统研究[D].淮南:安徽理工大学,2011.
[217]沙宝银,刘雨刚,杨春孝.基于组态王6.5的矿井通风主扇监控系统[J].辽宁工程技术大学学报,2005,24(s1):158-160.
[218]严桂,贾存良,黄文芳.基于CAN总线与组态王的瓦斯监控系统[J].仪表技术与传感器,2008(5):52-54.
[219]李兆坤.基于CAN总线与组态王的粮库监控系统的研究[D].成都:西南石油大学,2007.
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