This research combines laser ultrasonic techniques with the two-dimensional
Fourier transform (2D-FFT) to characterize adhesive bond properties. The e
xperimental procedure consists of measuring a series of equally spaced, tra
nsient Lamb waves in specimens consisting of aluminum plates joined with an
adhesive bond. The frequency spectrum (dispersion curves) for each specime
n are obtained by operating on these transient waveforms with the 2D-FFT. T
his study quantifies the effect of bond stiffness on the dispersion curves
of two different bonded specimens (a single aluminum plate with an adhesive
transfer tape attached to one side, and two aluminum plates joined with th
e same adhesive tape) and four adhesive bond conditions (un-aged, and three
different aging temperatures and times). The proposed procedure consists o
f first determining the frequency spectrum of the Lamb waves that propagate
in each of the two bonded specimens (plus a single plate); these measureme
nts provide the dispersion curves for each specimen in their un-aged state.
Degradation causes changes in the stiffness of an adhesive bond, which cau
ses changes in the dispersion curves of the aged specimens. Experimentally
measured dispersion curves are used to quantitatively track changes in the
bonded specimens, as a function of age. Finally, these experimental results
are interpreted in terms of an analytical model that replaces the adhesive
bond layer with a linear spring boundary condition. (C) 2000 Published by
Elsevier Science Ltd.