基于ZigBee技术的推进剂泄漏监测报警系统的设计与实现
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摘要
针对推进剂泄漏的严重危害性,提出一种以CC2530微控制器为核心,基于ZigBee技术的推进剂泄漏无线监测报警系统。系统主要包括无线推进剂泄漏监测气体传感器、双模监测报警主机和总控计算机。传感器与报警主机之间通过ZigBee无线技术进行信号传递,并通过以太网通信将报警主机采集的数据传送到监控中心的总控计算机上。试验结果表明,系统无线传输可靠,对推进剂的监测误差小于3%。该系统实现了推进剂泄漏的无线监测,极大降低了系统的安装布置时间,具有很强的机动性,不但实现了固定模式的推进剂泄漏监测,还实现了机动模式下的泄漏监测。
In view of the serious harm of propellant leakage, a monitoring alarm system for propellant leakage based on CC2530 microcontroller and ZigBee wireless technology is proposed in this paper. The system mainly consists of wireless propellant leakage monitoring gas sensor, dual mode monitoring alarm host and master computer. The sensor and the alarm host transmit the signal through the ZigBee wireless technology. The alarm host and the master computer in the monitoring room transmit the data collected by the alarm host through Ethernet. The experimental results show that the wireless transmission of the system is reliable, and the monitoring error of propellant is less than 3%. The system realizes the wireless monitoring of propellant leakage, greatly reduces the installation time of the system, and has a strong mobility, not only realizes the fixed mode propellant leakage monitoring, but also realizes the leakage monitoring under the maneuver mode.
In view of the serious harm of propellant leakage, a monitoring alarm system for propellant leakage based on CC2530 microcontroller and ZigBee wireless technology is proposed in this paper. The system mainly consists of wireless propellant leakage monitoring gas sensor, dual mode monitoring alarm host and master computer. The sensor and the alarm host transmit the signal through the ZigBee wireless technology. The alarm host and the master computer in the monitoring room transmit the data collected by the alarm host through Ethernet. The experimental results show that the wireless transmission of the system is reliable, and the monitoring error of propellant is less than 3%. The system realizes the wireless monitoring of propellant leakage, greatly reduces the installation time of the system, and has a strong mobility, not only realizes the fixed mode propellant leakage monitoring, but also realizes the leakage monitoring under the maneuver mode.
引文
[1] 丛继信,王力,张光友.液体推进剂职业中毒风险评价及防护对策研究[J].中国安全生产科学技术,2012,8(7):40-45.
[2] 刘志娟,郭斌.肼类火箭推进剂气体检测技术[J].低温与特气,2007(2):37-42.
[3] 王彦召,尚爱国,董振旗.基于PID技术的推进剂贮存环境监测控制系统[J].陕西工学院学报,2004(2):14-16.
[4] 刘佳,王立新.基于ZigBee的无线气体监测系统的设计[J].自动化与仪器仪表,2011(2):44-45,49.
[5] 王勇.基于ZigBee 矿井监控系统设计[J].国外电子测量技术,2017,36(7):58-61.
[6] 朱斌,唐勇,谭勇,等.基于ZigBee 的工控网数据采集传输系统设计[J].化工自动化及仪表,2010,37(4):81-85.
[7] 张冲,熊勇,房卫东,等.ZigBee网络性能测试系统研究[J].国外电子测量技术,2015,34(8):74-81.
[8] 陈自刚.基于CC2530的煤矿气体监测终端设计[J].南阳理工学院学报,2016,8(6):1-4.
[9] 王朋凯,杨文明.微弱直流电流放大电路的比较研究[J].电子测量技术,2018,41(11):45-50.
[10] 王磊,秦光远,潘文祥,等.基于气体传感器阵列的轿厢内有害气体监测系统的设计[J].信息通信,2017(4):74-75.
[11] 王春香,纪松波.采用ZigBee技术的温室环境监控系统设计[J].电子测量技术,2014,37(12):120-122,126.
[12] 焦尚彬,宋丹,张青,等.基于ZigBee无线传感器网络的煤矿监测系统[J].电子测量与仪器学报,2013,27(5):436-442.
[13] 郑争兵.面向有毒气体监测的无线传感器网络系统的实现[J].计算机与应用化学,2015,32(5):631-633.
[14] 温良,叶锦娇,王红尧,等.新一代煤矿井下监控系统研制[J].电子设计工程,2012,20(16):109-112.
[15] 李西文.受限空间的气体监测[J].中国石油和化工标准与质量,2017,37(9):28-29.
[2] 刘志娟,郭斌.肼类火箭推进剂气体检测技术[J].低温与特气,2007(2):37-42.
[3] 王彦召,尚爱国,董振旗.基于PID技术的推进剂贮存环境监测控制系统[J].陕西工学院学报,2004(2):14-16.
[4] 刘佳,王立新.基于ZigBee的无线气体监测系统的设计[J].自动化与仪器仪表,2011(2):44-45,49.
[5] 王勇.基于ZigBee 矿井监控系统设计[J].国外电子测量技术,2017,36(7):58-61.
[6] 朱斌,唐勇,谭勇,等.基于ZigBee 的工控网数据采集传输系统设计[J].化工自动化及仪表,2010,37(4):81-85.
[7] 张冲,熊勇,房卫东,等.ZigBee网络性能测试系统研究[J].国外电子测量技术,2015,34(8):74-81.
[8] 陈自刚.基于CC2530的煤矿气体监测终端设计[J].南阳理工学院学报,2016,8(6):1-4.
[9] 王朋凯,杨文明.微弱直流电流放大电路的比较研究[J].电子测量技术,2018,41(11):45-50.
[10] 王磊,秦光远,潘文祥,等.基于气体传感器阵列的轿厢内有害气体监测系统的设计[J].信息通信,2017(4):74-75.
[11] 王春香,纪松波.采用ZigBee技术的温室环境监控系统设计[J].电子测量技术,2014,37(12):120-122,126.
[12] 焦尚彬,宋丹,张青,等.基于ZigBee无线传感器网络的煤矿监测系统[J].电子测量与仪器学报,2013,27(5):436-442.
[13] 郑争兵.面向有毒气体监测的无线传感器网络系统的实现[J].计算机与应用化学,2015,32(5):631-633.
[14] 温良,叶锦娇,王红尧,等.新一代煤矿井下监控系统研制[J].电子设计工程,2012,20(16):109-112.
[15] 李西文.受限空间的气体监测[J].中国石油和化工标准与质量,2017,37(9):28-29.