Research on Ultrasonic Imaging for Arbitrarily Shaped Interface Based on Virtual Source

2018 IEEE Far East NDT New Technology & Application Forum (FENDT) Pub Date : 2018-07-01 DOI:10.1109/FENDT.2018.8681980

Yong Gan, Guo Chen, Chao Lu, Yao Chen

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Abstract

When the components with arbitrarily shaped are detected by the ultrasonic imaging test, the coupling medium such as immersion or wedge is unavoidable used for ensuring the coupling condition. In this state ultrasonic wave will propagate in the arbitrarily shaped two-media interface between coupling medium and component. For the traditional ultrasonic imaging method which the sound velocity is considered constant, the above condition would cause the wrong position of defects in the image. To overcome the problem, a method combining virtual source (VS) and synthetic aperture focusing technique (SAFT) was applied. Firstly, the sound propagation time of the first interface echo of each elements were measured. Then a series of virtual sources at the two-media interface were created by the time of flight (TOF) of two consecutive elements. Secondly, in virtue of the virtual sources, the two-segment sound propagation path from emitting elements to virtual sources and from here to focus points were respectively calculated. Last each point of the imaging region was focused by the delay and sum process of SAFT. The result showed the defect location of component were displayed accurately in the VS-SAFT image.

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基于虚拟源的任意形状界面超声成像研究

在超声成像检测任意形状的部件时，为了保证耦合条件，不可避免地要使用浸没或楔块等耦合介质。在这种状态下，超声波将在耦合介质与构件之间任意形状的双介质界面中传播。对于传统的声速恒定的超声成像方法，上述情况会导致缺陷在图像中的位置错误。为了克服这一问题，采用了虚拟光源(VS)和合成孔径聚焦技术(SAFT)相结合的方法。首先，测量了各单元第一界面回波的声传播时间;然后利用两个连续单元的飞行时间(TOF)在两介质界面上创建一系列虚拟源。其次，利用虚拟声源，分别计算了从发射单元到虚拟声源和从这里到焦点的两段声音传播路径。最后对成像区域的每个点进行延时和处理。结果表明，VS-SAFT图像能较准确地显示出构件的缺陷位置。

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2018 IEEE Far East NDT New Technology & Application Forum (FENDT)

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