Nothing Special   »   [go: up one dir, main page]

Loosening Identification of Multi-Bolt Connections Based on Wavelet Transform and ResNet-50 Convolutional Neural Network

Sensors (Basel). 2022 Sep 9;22(18):6825. doi: 10.3390/s22186825.

Abstract

A high-strength bolt connection is the key component of large-scale steel structures. Bolt loosening and preload loss during operation can reduce the load-carrying capacity, safety, and durability of the structures. In order to detect loosening damage in multi-bolt connections of large-scale civil engineering structures, we proposed a multi-bolt loosening identification method based on time-frequency diagrams and a convolutional neural network (CNN) using vi-bro-acoustic modulation (VAM) signals. Continuous wavelet transform was employed to obtain the time-frequency diagrams of VAM signals as the features. Afterward, the CNN model was trained to identify the multi-bolt loosening conditions from the raw time-frequency diagrams intelligently. It helps to get rid of the dependence on traditional manual selection of simplex and ineffective damage index and to eliminate the influence of operational noise of structures on the identification accuracy. A laboratory test was carried out on bolted connection specimens with four high-strength bolts of different degrees of loosening. The effects of different excitations, CNN models, and dataset sizes were investigated. We found that the ResNet-50 CNN model taking time-frequency diagrams of the hammer excited VAM signals, as the input had better performance in identifying the loosened bolts with various degrees of loosening at different positions. The results indicate that the proposed multi-bolt loosening identification method based on VAM and ResNet-50 CNN can identify bolt loosening with a reasonable accuracy, computational efficiency, and robustness.

Keywords: convolutional neural network; loosening identification; multi-bolt loosening; time-frequency diagram; vibro-acoustic modulation.

MeSH terms

  • Neural Networks, Computer*
  • Steel
  • Wavelet Analysis*

Substances

  • Steel

Grants and funding

This research was funded by the National Natural Science Foundation of China (No.51708164) and Shenzhen Science and Technology Program (No. KQTD20180412181337494, ZDSYS20201020162400001 and GJHZ20200731095802007).