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基于兰姆波成像方法的汽车搭接接头腐蚀监测

Corrosion Monitoring in Automotive Lap Joints Based on Imaging Methods of Lamb Waves.

作者信息

Ran Yunmeng, Qian Cheng, Wang Xiangfen, Zhang Weifang, Wang Rongqiao

机构信息

School of Energy and Power Engineering, Beihang University, Beijing 100191, China.

School of Reliability and Systems Engineering, Beihang University, Beijing 100191, China.

出版信息

Sensors (Basel). 2024 Dec 18;24(24):8092. doi: 10.3390/s24248092.

DOI:10.3390/s24248092
PMID:39771827
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11679932/
Abstract

Corrosion damage presents significant challenges to the safety and reliability of connected vehicles. However, traditional non-destructive methods often fall short when applied to complex automotive structures, such as bolted lap joints. To address this limitation, this study introduces a novel corrosion monitoring approach using Lamb wave-based weighted fusion imaging methods. First, the Minimum Variance Distortionless Response (MVDR) is utilized to process Lamb wave signals collected under bolt-loosening and bolt-tightening conditions to image the bolt locations. Second, based on the identified bolt positions, the weighted Reconstruction Algorithm for Probabilistic Inspection of Damage (RAPID) is applied to the Lamb wave signals acquired before and after corrosion, enabling precise imaging of the actual positions of the corroded bolts. Experiments are conducted on three-bolt lap joints in cases of single-corrosion and two-corrosion using A0 mode Lamb waves and piezoelectric sensor networks. The results demonstrate that the proposed method effectively images multiple types of damage and achieves maximum location deviations of 7.43 mm. This approach enables precise and visual multi-damage assessment, particularly in hard-to-access regions. When integrated with V2X-enabled (Vehicle-to-Everything) systems, the method offers potential for incorporation into automotive structural health monitoring systems for remote diagnosis in complex structures, thereby enhancing monitoring efficiency and accuracy.

摘要

腐蚀损伤给联网车辆的安全性和可靠性带来了重大挑战。然而,传统的无损检测方法应用于复杂的汽车结构(如螺栓搭接接头)时往往效果不佳。为解决这一局限性,本研究引入了一种基于兰姆波的加权融合成像方法的新型腐蚀监测方法。首先,利用最小方差无失真响应(MVDR)处理在螺栓松动和螺栓拧紧条件下采集的兰姆波信号,以对螺栓位置进行成像。其次,基于识别出的螺栓位置,将加权损伤概率检测重建算法(RAPID)应用于腐蚀前后采集的兰姆波信号,从而能够精确成像腐蚀螺栓的实际位置。使用A0模式兰姆波和压电传感器网络对三螺栓搭接接头在单腐蚀和双腐蚀情况下进行了实验。结果表明,所提出的方法能够有效地对多种类型的损伤进行成像,最大位置偏差为7.43毫米。这种方法能够实现精确且可视化的多损伤评估,特别是在难以触及的区域。当与支持车对万物(V2X)的系统集成时,该方法有望纳入汽车结构健康监测系统,用于复杂结构的远程诊断,从而提高监测效率和准确性。

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