Flexural free vibration as a non-destructive test for evaluation of viscoelastic properties of polymeric composites in bending direction

TL;DR

This paper introduces a simple, non-destructive flexural free vibration method using sound analysis to evaluate viscoelastic properties of fiber-reinforced polymer composites, providing a practical alternative to traditional testing.

Contribution

The study presents a novel NDT technique based on sound analysis of free vibration for assessing viscoelastic properties of composites, validated against standard DMTA measurements.

Findings

Good agreement between NDT and DMTA results.

Method effectively measures flexural elastic modulus.

Technique applicable to various fiber-reinforced composites.

Abstract

In many applications, viscoelastic properties of reinforced composites need to be determined prior to their real service life. Such properties can be assured by destructive and non-destructive tests. In this paper, a novel non-destructive test (NDT) method based on flexural free vibration is introduced to investigate the viscoelastic properties of fiber-reinforced composites. Three different types of industrial fibers (carbon, glass, and hemp) and an unsaturated polyester resin were selected to produce bar-shaped composites via pultrusion technique. These composite bars were used in a simple NDT method which just required a wooden hammer, two elastic jaws, a microphone and a recorder software program to perform the experiment. The composite bars were mounted on elastic jaws and hit by a wooden hammer at one end of the specimen as a perpendicular impulse. The produced sound at the other side of the bars was recorded. By analyzing the recorded sounds by means of fast Fourier transform (FFT), viscoelastic properties such as flexural elastic modulus and the loss parameter (Tan {\delta}) were calculated for the fiber-reinforced composites. For determination of flexural elastic modulus, the first three modes of vibration in FFT graphs were analyzed using Temuschenco theory. Also, Tan {\delta} was determined by analyzing the drop in the intensity of vibrational energy as a function of time. Although there was a slight discrepancy between the calculated values from the NDT method and the actual data from dynamic mechanical thermal analysis (DMTA) approach, a good agreement was achieved between NDT and DMTA results.