An AI-driven electromagnetic-triboelectric self-powered and vibration-sensing system for smart transportation

被引:1
|
作者
Tang, Minfeng [1 ,3 ]
Fang, Zheng [1 ,3 ]
Fan, Chengliang [3 ,5 ]
Zhang, Zutao [1 ,2 ]
Kong, Lingji [1 ,3 ]
Chen, Hongyu [4 ]
Zeng, Zhenhua [3 ,5 ]
Yang, Yun [3 ,4 ]
Qi, Lingfei [6 ]
机构
[1] Southwest Jiaotong Univ, Sch Mech Engn, Chengdu 610031, Peoples R China
[2] Chengdu Technol Univ, Chengdu 611730, Peoples R China
[3] Southwest Jiaotong Univ, Yibin Res Inst, Yibin, Peoples R China
[4] Southwest Jiaotong Univ, Sch Design, Chengdu 610031, Peoples R China
[5] Southwest Jiaotong Univ, Sch Informat Sci & Technol, Chengdu 611756, Peoples R China
[6] Guizhou Univ, Sch Mech Engn, Guiyang 550025, Guizhou, Peoples R China
来源
ENGINEERING STRUCTURES | 2025年 / 323卷
关键词
Train transportation; Self-powered and sensing; Electromagnetic-triboelectric; Inter-carriage vibration; Artificial Intelligence; ENERGY HARVESTER; NANOGENERATOR;
D O I
10.1016/j.engstruct.2024.119275
中图分类号
TU [建筑科学];
学科分类号
0813 ;
摘要
Developing energy recovery technologies in the transportation sector is crucial for reducing global carbon emissions and protecting the environment. Particularly significant is the research on self-powered and sensing technologies for train transportation, especially freight trains. This work introduces an AI-driven electromagnetic-triboelectric self-powered and vibration-sensing system (ESVS) designed for energy recovery and the sensing of inter-carriage vibrations in trains. The system primarily comprises a rope-driven motion conversion mechanism, a triboelectric nanogenerator, and a coaxial reversing electromagnetic generator. In verification, the electromagnetic generator demonstrated an impressive output power improvement rate of up to 547.13 % compared to conventional generators. It achieved effective and peak output powers of 186.89 mW and 0.47 W, respectively. The system successfully powered the sensor system by charging a battery with 108 mAh within 10 min. Additionally, a train status diagnostic system, which leverages sensing from a triboelectric nanogenerator and employs Artificial Intelligence (deep learning algorithms), was proposed, boasting a recognition accuracy of 99.78 %. Vibration tests conducted for a train scenario confirmed the feasibility of the system. The proposed ESVS offers the advantages of versatility and host-friendliness, providing an effective and practical solution for self-powered and sensing applications in smart transportation.
引用
收藏
页数:15
相关论文
共 50 条
  • [31] Self-Powered Wireless Sensing System Based on Triboelectric-Discharge Effect
    Si, Jiawei
    Yang, Jin
    Wang, Rui
    Wang, Kai
    Wang, Ziyuan
    Wu, Bozhi
    Li, Meng
    Nie, Meng
    Han, Lei
    IEEE TRANSACTIONS ON ELECTRON DEVICES, 2024, 71 (06) : 3874 - 3879
  • [32] Self-Powered Hybrid Motion and Health Sensing System Based on Triboelectric Nanogenerators
    Zhang, Maoqin
    Yan, Wei
    Ma, Weiting
    Deng, Yuheng
    Song, Weixing
    SMALL, 2024,
  • [33] Self-powered fall detection system using pressure sensing triboelectric nanogenerators
    Jeon, Seung-Bae
    Nho, Young-Hoon
    Park, Sang-Jae
    Kim, Weon-Guk
    Tcho, Il-Woong
    Kim, Daewon
    Kwon, Dong-Soo
    Choi, Yang-Kyu
    NANO ENERGY, 2017, 41 : 139 - 147
  • [34] Triboelectric-electromagnetic hybrid nanogenerator driven by wind for self-powered wireless transmission in Internet of Things and self-powered wind speed sensor
    Fan, Xueming
    He, Jian
    Mu, Jiliang
    Qian, Jichao
    Zhang, Ning
    Yang, Changjun
    Hou, Xiaojuan
    Geng, Wenping
    Wang, Xiangdong
    Chou, Xiujian
    NANO ENERGY, 2020, 68 (68)
  • [35] Self-powered wireless flexible sensing for food storage based on triboelectric-electromagnetic generator
    Wu, Zihao
    Chen, Xujun
    Wan, Zhengzhong
    Chi, Junjie
    Zhang, Ruihua
    Wang, Meng
    Song, Danyao
    Xiao, Xinqing
    MATERIALS TODAY SUSTAINABILITY, 2024, 26
  • [36] Self-driven sensing of acetylene powered by a triboelectric-electromagnetic hybrid generator
    Gui, Yingang
    Zhang, Wenhui
    Liu, Siyuan
    Li, Yukang
    Yang, Jiarui
    Jin, Gongyu
    Huang, Hua
    Yang, Pingan
    Gao, Mingyuan
    NANO ENERGY, 2024, 124
  • [37] Self-powered smart agriculture sensing using triboelectric nanogenerators based on living plant leaves
    Luo, Yu
    Cao, Xia
    Wang, Zhong Lin
    NANO ENERGY, 2023, 107
  • [38] Natural wood-based triboelectric nanogenerator as self-powered sensing for smart homes and floors
    Hao, Saifei
    Jiao, Jingyi
    Chen, Yandong
    Wang, Zhong Lin
    Cao, Xia
    NANO ENERGY, 2020, 75
  • [39] A chaotic pendulum triboelectric-electromagnetic hybridized nanogenerator for wave energy scavenging and self-powered wireless sensing system
    Chen, Xin
    Gao, Lingxiao
    Chen, Junfei
    Lu, Shan
    Zhou, Hong
    Wang, Tingting
    Wang, Aobo
    Zhang, Zhifei
    Guo, Shifeng
    Mu, Xiaojing
    Wang, Zhong Lin
    Yang, Ya
    NANO ENERGY, 2020, 69
  • [40] Self-powered wireless automatic countering system based on triboelectric nanogenerator for smart logistics
    Kang, Mengzhe
    Cui, Xin
    Zhou, Yuankai
    Han, Yiming
    Nie, Jiaheng
    Zhang, Yan
    NANO ENERGY, 2024, 123
12345