4/5/2025, 1:21:58 AM 星期六
Development of a high temperature resistant downhole vibration sensor based on the triboelectric nanogenerator
CSTR:
Author:
Affiliation:

1.Beijing Institute of Exploration Engineering, Beijing 100083, China;2.Faculty of Mechanical and Electronic Information, China University of Geosciences (Wuhan), Wuhan Hubei 430074, China;3.Faculty of Engineering and Technology, China University of Geosciences (Beijing), Beijing 100083, China

Clc Number:

P634

  • Article
  • | |
  • Metrics
  • |
  • Reference [26]
  • |
  • Related [20]
  • |
  • Cited by
  • | |
  • Comments
    Abstract:

    Excessive vibration frequency will damage drilling tools, affect efficiency and even cause downhole accidents, so it is necessary to measure the vibration frequency of downhole drilling tools in real time. In this paper, a high temperature resistant downhole vibration sensor based on the triboelectric nanogenerator is proposed. The sensor has not only vibration measurement function, but also power generation function. When the sensor measured the vibration frequency, the test showed that the measurement range was 0~8Hz, the measurement error was less than 4%, the signal/noise ratio was high, the anti-interference ability was strong, and the output signal amplitude was inversely proportional to the distance between the sensor and the vibration source. When the sensor was used for power generation, the test showed that the higher the vibration frequency, the greater the power generation. Its output voltage, output current and output power at 8Hz were 70V, 12×10-7A and 4.2×10-5W, respectively, demonstrating its potential as a downhole distributed generator. In addition, the sensor can be used at temperature less than 180℃ and relative humidity less than 90%, exhibiting strong adaptability.

    Reference
    [1] Kapitaniak M, Hamaneh V V, Chávez J P, et al. Unveiling complexity of drill-string vibrations: Experiments and modelling[J]. International Journal of Mechanical Sciences, 2015,101:324-337.
    [2] Kim Y Y, Simons L H. Drilling vibration measurements on a BOP stack[C]//Offshore Technology Conference, 1976.doi:10.4043/2620-MS.
    [3] 刘伟,周英操,王瑛,等.井下振动测量、分析原理研究[J].石油钻采工艺,2012,34(1):14-18.LIU Wei, ZHOU Yingcao, WANG Ying, et al. Study on downhole vibration measurement and analysis theory[J]. Oil Drilling & Production Technology, 2012,34(1):14-18.
    [4] Karel Kalista, Jindrich Liska, Jan Jakl. A vibration sensor-based method for generating the precise rotor orbit shape with general notch filter method for new rotor seal design testing and diagnostics[J]. Sensors, 2021,21(15):5249.
    [5] 陈波.井下钻柱振动测试方法研究[D].成都:西南石油大学,2015.CHEN Bo. Research on downhole drilling string vibration testing method[D]. Chengdu: Southwest Petroleum University, 2015.
    [6] Schen Emmanuel, A.D.Snell, B.H.Stanes. Optimization of bit drilling performance using a new small vibration logging tool[C]//SPE/IADC Drilling Conference. Amsterdam: 2005.
    [7] 翟小强,王瑛,刘伟.存储式井下振动测量工具的设计与室内试验[J].石油钻探技术,2011,39(4):111-114.ZHAI Xiaoqiang, WANG Ying, LIU Wei. Design and laboratory test of memory downhole vibration measurement tool[J]. Petroleum Drilling Techniques, 2011,39(4):111-114.
    [8] 吴蔚娓,沈雪峰.存储式井下振动测量仪的应用研究[J].石化技术,2019,26(2):79-80.WU Weiwei, SHEN Xuefeng. Research on the application of stored underground vibration survey[J]. Petrochemical Industry Technology, 2019,26(2):79-80.
    [9] Lines L A, Mauldin C L, Hill J W, et al. Advanced drilling dynamics sensor allows real-time drilling optimization, damage prevention and condition monitoring of RSS and LWD BHAs[C]//SPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers, 2014. doi:10.2118/170586-MS.
    [10] Millan E, Ringer M, Boualleg R, et al. Real-time drillstring vibration characterization using machine learning[C]//SPE/IADC International Drilling Conference and Exhibition. Society of Petroleum Engineers, 2019. doi:10.2118/194061-MS.
    [11] Fan F R, Tian Z Q, Wang Z L. Flexible triboelectric nanogenerator[J]. Nano Energy, 2012,1(2):328-334.
    [12] Qin K, Chen C, Pu X, et al. Magnetic array assisted triboelectric nanogenerator sensor for real-time gesture interaction[J]. Nano-micro Letters, 2021,13(1):1-9.
    [13] Vivekananthan V, Chandrasekhar A, Alluri N R, et al. A highly reliable, impervious and sustainable triboelectric nanogenerator as a zero-power consuming active pressure sensor[J]. Nanoscale Advances, 2020,2(2):746-754.
    [14] Liu C, Wang Y, Zhang N, et al. A self-powered and high sensitivity acceleration sensor with VQa model based on triboelectric nanogenerators (TENGs)[J]. Nano Energy, 2020,67:104228.
    [15] Zhou Q, Huang H, Wu C, et al. A self-powered sensor for drill pipe capable of monitoring rotation speed and direction based on triboelectric nanogenerator[J]. Review of Scientific Instruments, 2021,92(5):055006.
    [16] 吴川,杨朔,樊辰星,等.具有井下自发电及自传感功能的随钻测量新方法研究——以用于振动测量的井下摩擦纳米发电机为例[J].钻探工程,2021,48(4):47-53.WU Chuan, YANG Shuo, FAN Chenxing, et al. Research on a new measurement while drilling method with downhole self-powered and self-sensing function—An example of triboelectric nanogenerator used in downhole vibration measurement[J]. Drilling Engineering, 2021,48(4):47-53.
    [17] Yi F, Zhang Z, Kang Z, et al. Recent advances in triboelectric nanogenerator-based health monitoring[J]. Advanced Functional Materials, 2019,29(41):1808849.
    [18] Wang S, Tai H, Liu B, et al. A facile respiration-driven triboelectric nanogenerator for multifunctional respiratory monitoring[J]. Nano Energy, 2019,58:312-321.
    [19] Luo J, Gao W, Wang Z L. The triboelectric nanogenerator as an innovative technology toward intelligent sports[J]. Advanced Materials, 2021,33(17):2004178.
    [20] Zhang D, Shi J, Si Y, et al. Multi-grating triboelectric nanogenerator for harvesting low-frequency ocean wave energy[J]. Nano Energy, 2019,61:132-140.
    [21] Lin Z, Zhang B, Guo H, et al. Super-robust and frequency-multiplied triboelectric nanogenerator for efficient harvesting water and wind energy[J]. Nano Energy, 2019,64:103908.
    [22] Rahman M T, Rana S M S, Salauddin M, et al. A highly miniaturized freestanding kinetic-impact-based non-resonant hybridized electromagnetic-triboelectric nanogenerator for human induced vibrations harvesting[J]. Applied Energy, 2020,279:115799.
    [23] Zhang Q, Jiang C, Li X, et al. Highly efficient raindrop energy-based triboelectric nanogenerator for self-powered intelligent greenhouse[J]. ACS Nano, 2021.
    [24] Xiong J, Cui P, Chen X, et al. Skin-touch-actuated textile-based triboelectric nanogenerator with black phosphorus for durable biomechanical energy harvesting[J]. Nature Communications, 2018,9(1):1-9.
    [25] Wu C, Huang H, Li R, et al. Research on the potential of spherical triboelectric nanogenerator for collecting vibration energy and measuring vibration[J]. Sensors, 2020,20(4):1063.
    [26] Wu Chuan, Zhou Qing, Wen Guojun. Research on self-powered rotation speed sensor for drill pipe based on triboelectric-electromagnetic hybrid nanogenerator[J]. Sensors and Actuators A: Physical, 2021,326: 112723.
    Cited by
    Comments
    Comments
    分享到微博
    Submit
Get Citation
Share
Article Metrics
  • Abstract:
  • PDF:
  • HTML:
  • Cited by:
History
  • Received:October 14,2021
  • Revised:January 08,2022
  • Adopted:January 10,2022
  • Online: February 11,2022
  • Published: January 10,2022
Article QR Code