Premium
Ultrasonic determination of mechanical moduli of oriented semicrystalline polymers
Author(s) -
Lévesque Daniel,
Legros Nathalie,
Ajji Abdellah
Publication year - 1997
Publication title -
polymer engineering and science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.503
H-Index - 111
eISSN - 1548-2634
pISSN - 0032-3888
DOI - 10.1002/pen.11833
Subject(s) - materials science , transverse isotropy , viscoelasticity , ultrasonic sensor , isotropy , moduli , composite material , ultimate tensile strength , poisson's ratio , crystallinity , polymer , allowance (engineering) , amorphous solid , poisson distribution , acoustics , optics , mathematics , mechanical engineering , physics , crystallography , statistics , chemistry , engineering , quantum mechanics
Ultrasonics has been used for the determination of the mechanical properties of oriented semicrystalline polymers through time‐of‐flight measurements of elastic waves propagating in various directions within the material. While being nondestructive, such a method allows one to obtain more mechanical moduli with a better accuracy than the conventional tensile tests, especially regarding the shear properties and the Poisson's coefficients. Until now, the approach used to interpret the data was approximate and not rigorous. We present here a self‐consistent rigorous approach for interpreting time‐of‐flight data based on the group velocity including allowance for lateral displacement of the transmitted beam. Results are presented for roll‐drawn PET with various draw ratios. These samples are considered to have transversely isotropic symmetry. For the Young's moduli, comparisons are made with conventional tensile tests and the differences observed are interpreted in terms of viscoelastic efforts considering both the amorphous and crystalline phases.