High strain rate compression of epoxy micro pillars

TL;DR

This paper introduces a novel high strain rate micropillar compression setup using a pendulum-based nanoindentation device with force sensing, enabling the study of epoxy resin's strain rate sensitivity at microscale with validated results.

Contribution

A new high strain rate micropillar compression method using impact testing and force sensing is developed and validated for epoxy materials.

Findings

Significant strain rate sensitivity observed in epoxy resin.

The microscale results correlate well with macroscale behavior.

The setup overcomes previous instrumentation limitations.

Abstract

The study of the high strain rate mechanical behaviour of materials using micropillar compression tests has been hindered so far due to the lack of suitable instrumentation. In the present study, a novel high strain rate micropillar compression set-up is introduced. The high speed tests are carried out with the impact configuration of a pendulum-based nanoindentation device that was instrumented with force-sensing capability by means of a piezoelectric load cell. This is necessary due to the considerable inertia effects that make the actual applied force on the sample much higher than the actuated one. The proposed novel technique was successfully applied to study the mechanical behaviour of an epoxy resin over a wide range of strain rates. The results reveal a significant strain rate sensitivity that correlates well with that obtained for the same material at the macroscale, validating the novel set-up.