Pulse-echo-based third-order nonlinear ultrasound enhancement and its applications to microstructural characterizations in metal additive manufacturing
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引用次数: 0
Abstract
Second harmonic-based nonlinear ultrasonics is an emerging nondestructive testing technology that has recently gained attention owing to its high sensitivity for characterizing microstructures. However, this technique operates exclusively in the through-transmission mode and cannot be applied using the pulse-echo (PE) method, which is highly suitable for field applications owing to the phase-inversion effect. To address this limitation, we develop a PE-based third-order nonlinear ultrasonic technique for characterizing the microstructures of additive manufacturing (AM) components. Experiments demonstrate that the PE-based third-harmonic technique is highly sensitive to microstructural changes, including micro-oxide inclusions and grain structures formed during AM, whereas the conventional second-harmonic technique is not. An extensive discussion, supported by numerical simulations, is provided to explain these findings. The developed technique shows potential for in-situ monitoring in various industrial fields, including AM, because it enables single-sided measurements.
基于二次谐波的非线性超声技术是一种新兴的无损检测技术,由于其在表征微观结构方面的高灵敏度,最近备受关注。然而,由于相位反转效应,这种技术只能在直通传输模式下运行,无法使用脉冲回波(PE)方法,而这种方法非常适合现场应用。为了解决这一局限性,我们开发了一种基于 PE 的三阶非线性超声波技术,用于表征增材制造(AM)部件的微结构。实验证明,基于聚乙烯的三次谐波技术对微观结构变化(包括 AM 过程中形成的微氧化物夹杂物和晶粒结构)高度敏感,而传统的二次谐波技术则不敏感。为了解释这些发现,我们在数值模拟的支持下进行了广泛的讨论。所开发的技术可进行单面测量,因此具有在包括 AM 在内的各种工业领域进行原位监测的潜力。
期刊介绍:
Journal Name: Mechanical Systems and Signal Processing (MSSP)
Interdisciplinary Focus:
Mechanical, Aerospace, and Civil Engineering
Purpose:Reporting scientific advancements of the highest quality
Arising from new techniques in sensing, instrumentation, signal processing, modelling, and control of dynamic systems
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