基于自适应 2σ 阈值的可变时间窗强度映射的激光超声波检测 LAM 组件的缺陷

IF 7.1 1区 医学 Q1 ENGINEERING, BIOMEDICAL
Zhuangzhuang Wan , Xue Bai , Jian Ma , Zhaowen Xu , Yaolu Liu
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引用次数: 0

摘要

由于复杂的非平衡热力学,金属激光增材制造(LAM)中的冶金缺陷不可避免。我们设计了一套激光超声系统,用于检测逐层激光增材制造过程中的表面/近表面缺陷。提出了一种基于可变时间窗强度映射和自适应 2σ 阈值去噪的缺陷超声波成像方法。高斯混合物模型假设和期望最大化算法可以自动区分缺陷和背景噪声主导的成分,从而提供一个适应检测环境和表面粗糙度水平的自适应阈值。结果表明,脉冲激光照射表面缺陷时,缺陷边界的超声波反射会减弱远场超声波强度,从而实现缺陷大小和位置的表征。该方法适用于表面粗糙度高达 37.5 μm 的 LAM 样品。它可以检测直径和深度小至 0.5 毫米的表层和近表面缺陷,因此对增材制造中的在线缺陷检测具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Laser ultrasonic detection for defects of LAM components based on variable time window intensity mapping with adaptive 2σ thresholds

Metallurgical defects in metal laser additive manufacturing (LAM) are inevitable due to complex non-equilibrium thermodynamics. A laser ultrasonic system was designed for detecting surface/near-surface defects in the layer-by-layer LAM process. An approach was proposed for ultrasonic imaging of defects based on variable time window intensity mapping with adaptive 2σ threshold denoising. The Gaussian mixture model hypothesis and expectation-maximization algorithm can automatically differentiate between components dominated by defects and background noises, thereby providing an adaptive threshold that accommodates detection environments and surface roughness levels. Results show that the ultrasonic wave reflection at defect boundaries diminishes far-field ultrasonic intensity upon pulsed laser irradiation on surface defects, enabling defect size and location characterization. This method is applicable to LAM samples with a significant surface roughness of up to 37.5 μm. It can detect superficial and near-surface defects down to 0.5 mm in diameter and depth, making it significant for online defect detection in additive manufacturing.

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来源期刊
Photoacoustics
Photoacoustics Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
11.40
自引率
16.50%
发文量
96
审稿时长
53 days
期刊介绍: The open access Photoacoustics journal (PACS) aims to publish original research and review contributions in the field of photoacoustics-optoacoustics-thermoacoustics. This field utilizes acoustical and ultrasonic phenomena excited by electromagnetic radiation for the detection, visualization, and characterization of various materials and biological tissues, including living organisms. Recent advancements in laser technologies, ultrasound detection approaches, inverse theory, and fast reconstruction algorithms have greatly supported the rapid progress in this field. The unique contrast provided by molecular absorption in photoacoustic-optoacoustic-thermoacoustic methods has allowed for addressing unmet biological and medical needs such as pre-clinical research, clinical imaging of vasculature, tissue and disease physiology, drug efficacy, surgery guidance, and therapy monitoring. Applications of this field encompass a wide range of medical imaging and sensing applications, including cancer, vascular diseases, brain neurophysiology, ophthalmology, and diabetes. Moreover, photoacoustics-optoacoustics-thermoacoustics is a multidisciplinary field, with contributions from chemistry and nanotechnology, where novel materials such as biodegradable nanoparticles, organic dyes, targeted agents, theranostic probes, and genetically expressed markers are being actively developed. These advanced materials have significantly improved the signal-to-noise ratio and tissue contrast in photoacoustic methods.
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