低功耗一体式无线温压采集系统研究与设计
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摘要
针对换热站内温度与压力传感器有线安装和调试的不便性,设计了一套基于MSP430F149单片机的低功耗、一体式、无线温压采集系统。将传统的分体式温度、压力传感器设计为更紧凑和可靠的一体式温压传感器。对系统的硬件部分、软件部分进行了设计。通过窄脉宽瞬时供电、分时供电等方法实现了系统的低功耗设计。通过在实验室及换热站现场的相关测试实验,证明了该系统具有安装方便、稳定可靠、功耗低、精度高、便于维护等优点。
In view of the inconvenience of installation and debugging of the wired sensors in the heat exchange station,a set of low power consumption,all-in-one,wireless temperature-pressure measuring system was designed.The processor of the system is based on MSP430 F149.The traditional split separation temperature and pressure sensor were designed as a more compact and reliable integrated temperature-pressure sensor.The hardware and software parts of the system were designed.The low power consumption of the system was realized by means of narrow pulse width instantaneous power supply and time-sharing power supply.The test experiments were carried out in the lab and the heat exchanger station.The experimental results show that the system has the advantages of convenient installation,stable and reliable,low power consumption,high precision and easy maintenance.
In view of the inconvenience of installation and debugging of the wired sensors in the heat exchange station,a set of low power consumption,all-in-one,wireless temperature-pressure measuring system was designed.The processor of the system is based on MSP430 F149.The traditional split separation temperature and pressure sensor were designed as a more compact and reliable integrated temperature-pressure sensor.The hardware and software parts of the system were designed.The low power consumption of the system was realized by means of narrow pulse width instantaneous power supply and time-sharing power supply.The test experiments were carried out in the lab and the heat exchanger station.The experimental results show that the system has the advantages of convenient installation,stable and reliable,low power consumption,high precision and easy maintenance.
引文
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[12]党瑞荣,张宏伟,宋楠,等.高温高压井下压力传感器的补偿与校正[J].仪器仪表学报,2016(4):737-743.
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[14]侯培国,邢耀双,姚海兰,等.基于MSP430的微功耗无线压力变送器研究与设计[J].仪表技术与传感器,2011(2):19-21.
[15]杨明欣,王建波,于志强.基于TI单片机低功耗无线测温装置的设计[J].仪表技术与传感器,2008(8):87-91.
[2]林舒宜,张炳伟.集中供热智能无人值守换热站自控系统的设计与实现[J].自动化与仪表,2013(9):50-53.
[3]李红光,张国钧.换热站自动控制系统设计[J].自动化仪表,2015(3):36-39.
[4]田金云,朱清慧.储煤仓温度无线监控系统设计[J].煤炭技术,2015(11):274-275.
[5]魏纯,刘红艳.温室超低功耗无线传感器智控系统设计—基于MSP430和Zig Bee[J].农机化研究,2017(1):207-211.
[6]胡泽,李强,葛亮.低功耗无线压力变送器研究设计[J].自动化仪表,2013,34(12):87-90.
[7]潘长城,常青,王耀力.基于无线通信的井下低功耗压力传感器设计[J].仪表技术与传感器,2016(9):17-21.
[8]李贺,程祥,曾令国.基于nRF24L01芯片的近程无线通信系统设计[J].现代电子技术,2014(15):32-34.
[9]张修太,胡雪惠,翟亚芳,等.基于PT100的高精度温度采集系统设计与实验研究[J].传感技术学报,2010(6):812-815.
[10]王洪元,车轩,万军,等.一种WIA网络中的无线低功耗温度传感器节点设计[J].常州大学学报(自然科学版),2013,25(1):56-60.
[11]吕芮栋,张志文.以MSP430F149为核心的温度检测仪的硬件模块和软件设计[J].现代电子技术,2012(1):199-201.
[12]党瑞荣,张宏伟,宋楠,等.高温高压井下压力传感器的补偿与校正[J].仪器仪表学报,2016(4):737-743.
[13]付华圆,邹洪波,鲁仁全.基于MSP430F149的温湿度测控仪设计[J].机电工程,2011(4):493-499.
[14]侯培国,邢耀双,姚海兰,等.基于MSP430的微功耗无线压力变送器研究与设计[J].仪表技术与传感器,2011(2):19-21.
[15]杨明欣,王建波,于志强.基于TI单片机低功耗无线测温装置的设计[J].仪表技术与传感器,2008(8):87-91.
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