|本期目录/Table of Contents|

[1]张 鑫,张向顺,赵惟诚,等.基于DSP和CAN的机电环境设备监控系统模块化设计[J].工业仪表与自动化装置,2021,(06):21-25+87.[doi:10.19950/j.cnki.cn61-1121/th.2021.06.004]
 ZHANG Xin,HANG Xiangshun,ZHAO Weicheng,et al.Modular design of mechanical and electrical environment equipment monitoring system based on DSP and CAN[J].Industrial Instrumentation & Automation,2021,(06):21-25+87.[doi:10.19950/j.cnki.cn61-1121/th.2021.06.004]
点击复制

基于DSP和CAN的机电环境设备监控系统模块化设计

《工业仪表与自动化装置》[ISSN:1000-0682/CN:61-1121/TH]

卷:
期数:
2021年06期
页码:
21-25+87
栏目:
出版日期:
2021-12-15

文章信息/Info

Title:
Modular design of mechanical and electrical environment equipment monitoring system based on DSP and CAN
作者:
张 鑫张向顺赵惟诚郭永志
(中建八局第三建设有限公司,江苏 南京210000)
Author(s):
ZHANG Xin HANG Xiangshun ZHAO Weicheng GUO Yongzhi
(The Third Construction Co., Ltd. of China Construction Eighth Engineering Bureau,NanJing 210000,China)
关键词:
DSPCAN总线机电环境设备监控系统模块化设计CAN2.0 B协议
Keywords:
DSP CAN bus electromechanical environmental equipment monitoring system modular design CAN2.0 protocol B
分类号:
TM764
DOI:
10.19950/j.cnki.cn61-1121/th.2021.06.004
文献标志码:
A
摘要:
为提升机电环境设备监控系统的实时性和准确性,降低机电环境设备的故障率,模块化设计基于DSP和CAN的机电环境设备监控系统。模块化设计综合采集模块、通信管理模块和分析模块。综合采集模块选取DSP为核心处理器,实现信号的实时采集,并将信号转换成电参量,传输至通信管理模块;通信管理模块以CAN总线的控制器TMS320LF2407A作为核心处理器,通过CAN2.0B协议,实现CAN总线数据的实时通信,提升通信的可靠性和抗干扰能力;分析模块采用改进传统连接树传播方法,实现设备故障的实时检测。经实验验证:该系统采集的频率误差全部未大于2 Hz,具有较好的信号采集能力;故障检测率始终在95%以上;故障隔离率始终保持在96%以上。该系统的安全性与可管理性较强,存储形式简便,数据库并未出现较大空间限制,设备故障的实时监控效果好,能够降低机电环境设备的故障率。
Abstract:
In order to improve the real-time and accuracy of electromechanical environmental equipment monitoring system and reduce the failure rate of electromechanical environmental equipment,the DSP and CAN monitoring system based on electromechanical environmental equipment is modular designed.Modular design of integrated acquisition module,communication management module,and analysis module.The comprehensive collection module selects DSP as the core processor to realize the real-time acquisition of the signal,and transforms the signal into an electrical parameter,and transmits it to the communication management module.The communication management module takes the controller TMS320LF2407A of CAN bus as the core processor,realizes the real-time communication of CAN bus data and improves the communication reliability and anti-interference capability;the analysis module improves the traditional connection tree communication method to realize the real-time detection of equipment failure.Through experimental verification:the frequency error collected by the system is not more than 2 Hz, with good signal acquisition capability;fault detection rate is always above 95%;fault isolation rate is always above 96%.The system has strong safety and manageability, simple storage form, no large space restrictions in the database, and good real-time monitoring effect of equipment failure,which can reduce the failure rate of electromechanical environment equipment.

参考文献/References:

[1] 郑店坤,许同乐,连瑞德,等.基于CAN总线的分布式监测预警系统设计[J].电测与仪表,2019, 56(4):37-42.

[2] 宋益东.基于CAN总线多主通信技术的监控分站设计[J].煤矿安全,2020,51(07):104-107.
[3] 丁友强,刘彦伟,杨丽,等.基于Android和CAN总线的玉米播种机监控系统研究[J].农业机械学报,2019,50(12):33-41+62.
[4] 刘昌明,时朵,黄跃文,等.基于CAN总线的固定测斜仪数据采集系统设计[J].仪表技术与传感器,2020(05):53-57.
[5] 张鹏翀,张宏.基于CAN总线的可燃危险品库安全监控系统设计[J].舰船科学技术,2020,42(05):156-158.
[6] 刘雨青,姜亚锋,邢博闻,等.基于无人船装置的大水域环境监测系统设计[J]. 船舶工程, 2019,41(01):17-22+73.
[7] 魏永武,王海亮,朱奇先,等.基于DSP+CPLD的矿井提升机用MMC控制系统[J].煤炭技术,2019,38(09):159-162.
[8] 何高清,章路平.基于CAN总线的某特种机器人控制系统设计与实现[J].机床与液压,2020,48(04):86-90.
[9] 汤旺杰,金华标,李鹤鸣.基于CAN冗余的船舶数据采集与远程监控系统[J].舰船科学技术,2020,42(05):144-147.
[10] 王朝阳,高强,李洪祥,等.基于CAN总线的智能电动执行器控制系统设计[J].传感技术学报,2020,33(05):763-768.
[11] 高原源,王秀,杨硕,等.基于CAN总线的播种深度监测评价系统研究[J].农业机械学报,2019,50(12):23-32.
[12] 范振瑞.基于CAN总线的船舶柴油机状态监测系统[J]. 舰船科学技术,2019,41(20):79-81.
[13] 王文彬,邓飞云,陈清,等.基于模块化软件的船用乏汽冷却监控系统研制[J].船舶工程,2019,41(10):91-97.
[14] 胡亚楠.基于CAN总线的车身电器控制系统硬件设计研究[J].电视技术,2020,44(05):61-62.
[15] 孙松丽,朱文亮,黄晓华,等.基于CANopen总线的弯管机多轴运动控制系统设计与实现[J].机床与液压,2019, 47(23):153-159.

相似文献/References:

[1]王彩霞,周志文.基于DSP的有源电力滤波器设计[J].工业仪表与自动化装置,2014,(04):23.
 WANG Caixia,ZHOU Zhiwen.The design of active power filter based on DSP[J].Industrial Instrumentation & Automation,2014,(06):23.
[2]周月阳,陈 波.平锁缝纫机运动控制卡设计[J].工业仪表与自动化装置,2014,(05):26.
 ZHOU Yueyang,CHEN Bo.Designing of the lockstitch button holing machine motion control card[J].Industrial Instrumentation & Automation,2014,(06):26.
[3]韩向可,段立霞.基于DSP的风电场电能质量监测系统设计[J].工业仪表与自动化装置,2014,(06):50.
 HAN Xiangke,DUAN Lixia.Design of wind farm power quality monitoring system based on DSP[J].Industrial Instrumentation & Automation,2014,(06):50.
[4]严 辉,方 正.基于CAN总线的门禁读卡控制器设计[J].工业仪表与自动化装置,2016,(04):64.
 YAN Hui,FANG Zheng.The design of the access control card reader based on CAN bus[J].Industrial Instrumentation & Automation,2016,(06):64.
[5]周志文,王晓燕.基于DSP的直流磁控溅射电源设计[J].工业仪表与自动化装置,2017,(02):47.
 ZHOU Zhiwen,WANG Xiaoyan.Magnetron sputtering DC power supply design based on DSP[J].Industrial Instrumentation & Automation,2017,(06):47.
[6]金洪吉.基于CAN总线的数字可调电源系统[J].工业仪表与自动化装置,2017,(03):85.
 JIN Hongji.The digital adjustable power supply based on CAN bus[J].Industrial Instrumentation & Automation,2017,(06):85.
[7]官国栋,安世奇.LED集鱼灯控制系统的设计与实现[J].工业仪表与自动化装置,2017,(04):84.
 GUAN Guodong,AN Shiqi.Design and implementation of distributed control system in LED[J].Industrial Instrumentation & Automation,2017,(06):84.
[8]黄文力,李 响,付金光.基于VS2010的可视化DSP多直流电机控制系统[J].工业仪表与自动化装置,2018,(04):65.[doi:1000-0682(2018)04-0000-00]
 HUANG Wenli,LI Xiang,FU Jinguang.The visual multi-DC-motor control system of DSP based on VS2010[J].Industrial Instrumentation & Automation,2018,(06):65.[doi:1000-0682(2018)04-0000-00]
[9]李欣玉,范蟠果.应用于三菱PLC的CAN总线通信转换装置研究[J].工业仪表与自动化装置,2021,(03):134.[doi:10.19950/j.cnki.cn61-1121/th.2021.03.029]
 LI Xinyu,FAN Panguo.Research on CAN bus communication conversion device applied to Mitsubishi PLC[J].Industrial Instrumentation & Automation,2021,(06):134.[doi:10.19950/j.cnki.cn61-1121/th.2021.03.029]
[10]尹恩华,高振天,孙 奎.站台门门控单元远程在线程序升级技术设计与实现[J].工业仪表与自动化装置,2022,(02):62.[doi:10.19950/j.cnki.cn61-1121/th.2022.02.013]
 YIN Enhua,GAO Zhentian,SUN Kui.Design and implementation of remote online program upgrade technology for platform screen door control unit[J].Industrial Instrumentation & Automation,2022,(06):62.[doi:10.19950/j.cnki.cn61-1121/th.2022.02.013]

备注/Memo

备注/Memo:
收稿日期:2021-07-04
作者简介:张鑫(1982),男,吉林长春人,本科,研究方向为建筑环境与设备工程。
更新日期/Last Update: 1900-01-01