基于STM32的航站楼环境参数实时无线监测系统
Real Time Monitoring System for Environmental Parameters in Terminal Based on STM32
DOI: 10.12677/CSA.2021.116168, PDF,   
作者: 杜 鹏:中国南方航空南阳基地,河南 南阳
关键词: CO2温度监测系统航站楼节能检测器CO2 Concentration Temperature Monitoring System Terminal Energy Conservation Detector
摘要: 过程控制系统具有的大滞后性给航站楼环境控制节能带来挑战。为提高航站楼内环境控制系统能效,开发基于STM32和Zigbee技术的航站楼环境参数实时无线监测系统。采用STM32F103ZET6微控制器制作低功耗检测节点,为降低系统损耗灵活调整数据传输周期。在Visual Studio平台通过开辟多线程实现监测软件高效率运行。实验和应用结果表明,该系统与固定周期数据传输系统相比,功耗显著降低,系统稳定性好;在提高能效方面,CO2浓度比温度随客流量变化更加灵敏,延迟时间短,可为航站楼空调系统提高能效作为参考依据。
Abstract: Process control system is a serious delayed system, which brings challenges for environmental quality control systems in terminal. In order to improve the energy efficiency of environmental control system, a real-time monitoring system for terminal environmental parameters is developed based on STM32 and Zigbee technology. Low consumption detector node is developed by using STM32F103ZET6 as microcontroller. The system consumption is reduced through the data transmission mechanism of changing period. Efficient monitoring software is developed by creating multi-threads on the platform of Visual Studio. The experiment and application results show that the system has a lower consumption and better network stability compared with fixed period data transmission system. In terms of improving energy efficiency, CO2 concentration is more sensitive and has shorter delay time to the change of the passenger flow than temperature. It can be used as an important parameter to improve the energy efficiency of air conditioning system in terminal.
文章引用:杜鹏. 基于STM32的航站楼环境参数实时无线监测系统[J]. 计算机科学与应用, 2021, 11(6): 1627-1636. https://doi.org/10.12677/CSA.2021.116168

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