| 5 | 0 | 0 |
 Reads |
 Downloads |
 Citas |
Because of the power supply and communication wiring difficulties caused by the rotating mechanical components in the monitoring system, and the disadvantages of the existing conductive slip ring technology, such as easy wear and short life, this paper designed a rotating mechanical component monitoring system based on wireless power supply. Firstly, theoretical analysis, simulation verification and hardware design were conducted on the LCC⁃S type magnetically coupled wireless power transmission system, realizing a wireless power supply subsystem capable of non⁃contact wireless power transmission. Secondly, a monitoring subsystem was designed, which could collect the temperature and vibration data of multiple points in the rotating mechanical components in real time and transmit them to the upper computer via wireless communication. Finally, the effectiveness of the system was verified by building a rotating experimental platform to simulate the rotational motion of mechanical components. To sum up, the designed system provides a feasible technical solution for the wireless monitoring of rotating mechanical components.
[1] 王斌.基于深度学习的旋转机械部件故障诊断与寿命预测研究[D].保定:河北农业大学,2023.
[2] Ghosh R, Montanari G C, Seri P. Partial discharge measurement and condition monitoring in power ⁃ electronics controlled rotating machines: issues and solutions in advanced electrified transport and aerospace applications [C]// 2020 8th International Conference on Condition Monitoring and Diagnosis (CMD). Phuket, Thailand: IEEE, 2020: 358⁃363.
[3] Hong Shunsheng, Wang Yingpeng, Tang Chunsen, et al. Research and design of rotary multi⁃channel wireless power transmission system [C]// 2022 Wireless Power Week (WPW). Bordeaux, France: IEEE, 2022: 879⁃883.
[4] Liu Xihui, Zhang Guangtuo, Zhang Ying, et al. Investigation of accelerated life test on the conductive slip ring of ship′s platform inertial navigation equipment [C]// 2022 International Conference on Cloud Computing, Big Data and Internet of Things (3CBIT). Wuhan, China: IEEE, 2022: 203⁃207.
[5] Chen Tao, Wang Zhongke, Qin Guangzhao, et al. Magnetic coupling resonant power wireless transmission system based on wireless energy transmission [C]// 2023 International Conference on Internet of Things, Robotics and Distributed Computing (ICIRDC). Rio De Janeiro, Brazil: IEEE, 2023: 612⁃616.
[6] Ye Yuling, Peng Chongsen, Wang Yizhang, et al. Wireless power transmission system via magnetic resonance coupling platform [C]// 2019 IEEE International Conference on Mechatronics and Automation (ICMA). Tianjin, China: IEEE, 2019: 1772⁃1777.
[7] 王立新,郭凰,杨佳宇,等.无线通信在结构健康监测系统的应用研究综述[J].科学技术与工程,2023,23(6):2229⁃2241.
[8] 陈汪洋.磁耦合谐振式无线充电的电路设计[J].集成电路应用,2023,40(7):14⁃15.
[9] 张明皓,陈希有,牟宪民,等.旋转物体上电子设备无线供电技术研究[J].电工电能新技术,2020,39(7):54⁃61.
[10] 宁世超.磁耦合谐振式无线充电系统设计与仿真[D].阜新:辽宁工程技术大学,2014.
[11] 英飞凌科技公司.IRFZ44N数据手册[EB/OL].[2010⁃09⁃21]. https://www.alldatasheetcn.com/datasheet⁃pdf/view/141116/IRF/ IRFZ44NPBF.html.
[12] 英飞凌科技公司.IR2110数据手册[EB/OL].[2019⁃03⁃06]. https://www. alldatasheetcn. com/datasheet ⁃ pdf/view/1238026/ INFINEON/IR2110.html.
[13] 上海雷卯电子科技有限公司.SR5200数据手册[EB/OL]. [2019⁃12⁃01]. https://www. alldatasheetcn. com/datasheet ⁃ pdf/ view/1347761/LEIDITECH/SR5200.html.
[14] 胡连华,徐卓,陈海峰.LoRa与NB⁃IoT通信技术研究现状[J].传感器世界,2021,27(9):1⁃6.
[15] 房丽媛,张妍,雷千龙,等.基于STM32的电机实时状态监测系统设计[J].工业控制计算机,2024,37(1):159⁃161.
Basic Information:
DOI:10.16652/j.issn.1004⁃373x.2026.09.020
Citation Information:
[1]Li Jiaxing12, Liang Guangsheng2, Liu Shoubao1 ,et al.Design of rotating mechanical component monitoring system based on wireless power supply[J].Modern Electronic Technique,2026(9):133-140.DOI:10.16652/j.issn.1004⁃373x.2026.09.020.