Abstract
At low frequencies, in thin plates the phase velocity of the guided A0 mode can become slower than that of the ultrasound velocity in air. Such waves do not excite leaky waves in the surrounding air, and therefore, it is impossible to excite and receive them by conventional air-coupled methods. The objective of this research was the development of an air-coupled technique for the reception of slow A0 mode in thin plastic films. This study demonstrates the feasibility of picking up a subsonic A0 mode in plastic films by air-coupled ultrasonic arrays. The air-coupled reception was based on an evanescent wave in air accompanying the propagating A0 mode in a film. The efficiency of the reception was enhanced by using a virtual array which was arranged from the data collected by a single air-coupled receiver. The signals measured at the points corresponding to the positions of the phase-matched array were recorded and processed. The transmitting array excited not only the A0 mode in the film, but also a direct wave in air. This wave propagated at ultrasound velocity in air and was faster than the evanescent wave. For efficient reception of the A0 mode, the additional signal-processing procedure based on the application of the 2D Fourier transform in a spatial–temporal domain. The obtained results can be useful for the development of novel air-coupled ultrasonic non-destructive testing techniques.
Highlights
Ultrasonic guided Lamb waves are widely used for the non-destructive testing and evaluation of various objects and structures such as composite plates [1,2], metal pipes [3], composite panels [4], and paper products [5,6,7].Usually, guided waves are excited by an ultrasonic transducer coupled to a test structure by a coupling liquid
At lower fd values at low frequencies, in the thin plates for some materials, f and/or the A0 mode phase velocity can become slower than the ultrasound velocity in air
There is no leaky ultrasonic wave, which means that it is not possible to excite and receive such a wave by ultrasonic transducers deflected at an angle according to Snell’s law
Summary
Ultrasonic guided Lamb waves are widely used for the non-destructive testing and evaluation of various objects and structures such as composite plates [1,2], metal pipes [3], composite panels [4], and paper products [5,6,7]. The air-coupled ultrasonic technique has been used for defect detection in composite materials [14,18,19,22], polymer pipes [23], and cardboard tubes [24] and for the non-destructive testing of square-shaped CFRP composite rods [25] They enable detection of delamination type defects, pores and other non-uniformities, and measurement of their position and dimensions. At lower fd values at low frequencies, in the thin plates for some materials, f and/or the A0 mode phase velocity can become slower than the ultrasound velocity in air In this case, the materials should possess a low ratio of Young’s modulus to density E/ρ. Mode phase velocity was slower than the velocity in air (Figure 2)
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