Thermal effects on a passive wireless antenna sensor for strain and crack sensing

被引:7
|
作者
Yi, Xiaohua [1 ]
Vyas, Rushi [2 ]
Cho, Chunhee [1 ]
Fang, Chia-Hung [1 ]
Cooper, James [2 ]
Wang, Yang [1 ]
Leon, Roberto T. [3 ]
Tentzeris, Manos M. [2 ]
机构
[1] Georgia Inst Technol, Sch Civil & Environm Eng, Atlanta, GA 30332 USA
[2] Georgia Inst Technol, Sch Elect & Comp Engn, Atlanta, GA 30332 USA
[3] Virginia Polytech Inst & State Univ, Dept Civil & Engn Eng, Blacksburg, VA 24061 USA
来源
SENSORS AND SMART STRUCTURES TECHNOLOGIES FOR CIVIL, MECHANICAL, AND AEROSPACE SYSTEMS 2012, PTS 1 AND 2 | 2012年 / 8345卷
关键词
passive wireless sensor; folded patch antenna; strain sensor; crack sensor; thermal effect; RFID;
D O I
10.1117/12.914833
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
For application in structural health monitoring, a folded patch antenna has been previously designed as a wireless sensor that monitors strain and crack in metallic structures. Resonance frequency of the RFID patch antenna is closely related with its dimension. To measure stress concentration in a base structure, the sensor is bonded to the structure like a traditional strain gage. When the antenna sensor is under strain/deformation together with the base structure, the antenna resonance frequency varies accordingly. The strain-related resonance frequency variation is wirelessly interrogated and recorded by a reader, and can be used to derive strain/deformation. Material properties of the antenna components can have significant effects on sensor performance. This paper investigates thermal effects through both numerical simulation and temperature chamber testing. When temperature fluctuates, previous sensor design (with a glass microfiber-reinforced PTFE substrate) shows relatively large variation in resonance frequency. To improve sensor performance, a new ceramic-filled PTFE substrate material is chosen for re-designing the antenna sensor. Temperature chamber experiments are also conducted to the sensor with new substrate material, and compared with previous design.
引用
收藏
页数:11
相关论文
共 50 条
  • [41] Crack-Based Sensor with Microstructures for Strain and Pressure Sensing
    Kim, Nakung
    Yun, Daegeun
    Hwang, Injoo
    Yoon, Gibaek
    Kang, Seong Min
    Choi, Yong Whan
    SENSORS, 2023, 23 (12)
  • [42] A Passive and Wireless Sensor Based on RFID Antenna for Detecting Mechanical Deformation
    He, Yuan
    Li, Meng Meng
    Wan, Guo Chun
    Tong, Mei Song
    IEEE OPEN JOURNAL OF ANTENNAS AND PROPAGATION, 2020, 1 : 426 - 434
  • [43] A passive wireless gas sensor based on microstrip antenna with copper nanorods
    Elwi, T.A. (taelwi@ualr.edu), 1600, Electromagnetics Academy
  • [44] Thermal Sensor Boiler Monitoring based on Wireless Sensing
    Duan, Aixia
    Huang, Yongzhi
    Duan, Yanling
    Wang, Qiuhong
    INTERNATIONAL JOURNAL OF ONLINE ENGINEERING, 2018, 14 (08) : 107 - 120
  • [45] A Passive, Wireless Strain Sensor Using a Microfabricated Magnetoelastic Beam Element
    Pepakayala, Venkatram
    Gianchandani, Yogesh B.
    2013 IEEE SENSORS, 2013, : 1855 - 1858
  • [46] Wireless Passive Flexible Strain Sensor Based on Aluminium Nitride Film
    Li, Meipu
    Zhang, Lei
    Dong, Helei
    Wang, Ya
    Yan, Xiawen
    Hao, Zhuya
    Tan, Qiulin
    IEEE SENSORS JOURNAL, 2022, 22 (04) : 3074 - 3079
  • [47] Passive and Wireless Strain Sensor based on LC Circuit with Lamination Fabrication
    Tu, Cheng
    Liu, Chin-Liang
    Lee, Meng-Shiue
    Hsu, Wensyang
    2017 IEEE 12TH INTERNATIONAL CONFERENCE ON NANO/MICRO ENGINEERED AND MOLECULAR SYSTEMS (NEMS), 2017, : 303 - 306
  • [48] Wireless Passive LC Temperature and Strain Dual-Parameter Sensor
    Wang, Ya
    Tan, Qiulin
    Zhang, Lei
    Lin, Baimao
    Li, Meipu
    Fan, Zhihong
    MICROMACHINES, 2021, 12 (01) : 1 - 10
  • [49] A Configurable Dielectric Resonator-Based Passive Wireless Sensor for Crack Monitoring
    Zhang, Jun
    Huang, Hanxi
    Huang, Chutian
    Zhang, Bingsheng
    Li, Yao
    Wang, Kun
    Su, Dongming
    Tian, Gui Yun
    IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION, 2019, 67 (08) : 5746 - 5749
  • [50] Development of a wireless and passive temperature-compensated SAW strain sensor
    Wang, Wen
    Xue, Xufeng
    Fan, Shuyao
    Liu, Mengwei
    Liang, Yong
    Lu, Minghui
    SENSORS AND ACTUATORS A-PHYSICAL, 2020, 308
12345