An efficient crack detection and leakage monitoring in liquid metal pipelines using a novel BRetN and TCK-LSTM techniques

IF 3 4区 计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Multimedia Tools and Applications Pub Date : 2024-09-06 DOI:10.1007/s11042-024-20170-6
Praveen Sankarasubramanian
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Abstract

Nowadays, the pipeline system has the safest, most economical, and most efficient means of transporting petroleum products and other chemical fluids. But, the faults in pipelines cause resource wastage and environmental pollution. Most of the existing works focused either on the surface Crack Detection (CD) or Leakage Detection (LD) of pipes with limited features. Hence, efficient crack detection and leakage monitoring are proposed based on the Acoustic Emission (AE) signal and AE image features using a new Berout Retina Net (BRetN) and Tent Chaotic Kaiming-centric Long Short Term Memory (TCK-LSTM) methodologies. The process initiates from the gathering of input data, followed by preprocessing. Then, the cracks are detected by utilizing Berout Retina Net (BRetN), and the features of AE signals are retrieved. On the other hand, the AE signal is transformed into an AE image using Continuous Wavelet Transform (CWT). Further, the AE image features are extracted, followed by the integration of both the AE signal and AE image features. Further, the optimal features are chosen by using Gorilla Troops Optimizer (GTO). Eventually, the TCK-LSTM model is used for detecting the leakage level of the pipeline. The experimental outcomes illustrated that the proposed framework detected crack and leakage levels with 98.14% accuracy, 95.37% precision, and 98.84% specificity when analogizing over the existing techniques.

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使用新型 BRetN 和 TCK-LSTM 技术高效检测液态金属管道中的裂缝并进行泄漏监测
如今,管道系统已成为最安全、最经济、最高效的石油产品和其他化学液体运输手段。但是,管道故障会造成资源浪费和环境污染。现有的大多数研究都侧重于管道表面裂缝检测(CD)或泄漏检测(LD),但功能有限。因此,我们提出了基于声发射(AE)信号和 AE 图像特征的高效裂缝检测和泄漏监测方法,并采用了新的 Berout Retina Net(BRetN)和 Tent Chaotic Kaiming-centric Long Short Term Memory(TCK-LSTM)方法。该过程从收集输入数据开始,然后进行预处理。然后,利用 Berout Retina Net(BRetN)检测裂缝,并检索 AE 信号的特征。另一方面,利用连续小波变换 (CWT) 将 AE 信号转换为 AE 图像。然后,提取 AE 图像特征,再对 AE 信号和 AE 图像特征进行整合。然后,使用大猩猩部队优化器(GTO)选择最佳特征。最后,使用 TCK-LSTM 模型检测管道的泄漏程度。实验结果表明,与现有技术相比,拟议框架检测裂缝和泄漏水平的准确率为 98.14%,精确率为 95.37%,特异性为 98.84%。
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来源期刊
Multimedia Tools and Applications
Multimedia Tools and Applications 工程技术-工程:电子与电气
CiteScore
7.20
自引率
16.70%
发文量
2439
审稿时长
9.2 months
期刊介绍: Multimedia Tools and Applications publishes original research articles on multimedia development and system support tools as well as case studies of multimedia applications. It also features experimental and survey articles. The journal is intended for academics, practitioners, scientists and engineers who are involved in multimedia system research, design and applications. All papers are peer reviewed. Specific areas of interest include: - Multimedia Tools: - Multimedia Applications: - Prototype multimedia systems and platforms
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