Dynamic impact testing of cellular solids and lattice structures: Application of two-sided direct impact Hopkinson bar

Highlights

• Direct impact Hopkinson bar with two-sided instrumentation used for impact testing.

• Wave separation method allowed for significant extension of the experiment duration.

• Wave separation and specimen’s response verified with digital image correlation.

• Experimental setups with both linear elastic and visco-elastic bars used.

• Metal foams, additively manufactured lattices and hybrid auxetic metamaterials tested.

Abstract

Direct impact testing with a Hopkinson bar is, nowadays, a very popular experimental technique for investigating the behavior of cellular materials, e.g., lattice metamaterials, at high strain-rates as it overcomes several limitations of the conventional Split Hopkinson Pressure Bar (SHPB). However, standard direct impact Hopkinson bars (DIHB) have only single-sided instrumentation complicating the analysis. In this paper, a DIHB apparatus instrumented with conventional strain-gauges on both bars (a so called Open Hopkinson Pressure Bar - OHPB) is used for dynamic impact experiments of cellular materials. Digital image correlation (DIC) is used as a tool for investigating the displacements and velocities at the faces of the bars. A straight-forward wave separation technique combining the data from the strain-gauges with the DIC is adopted to increase the experiment time window multiple times. The experimental method is successfully tested at impact velocities in a range of $5-30\text{m}·{\text{s}}^{-1}$ with both linear elastic and visco-elastic bars of a medium diameter. It is shown that, under certain circumstances, a simple linear elastic model is sufficient for the evaluation of the measurements with the visco-elastic bars, while no additional attenuation and phase-shift corrections are necessary. The applicability of the experimental method is demonstrated on various experiments with conventional metal foams, hybrid foams, and additively manufactured auxetic lattices subjected to dynamic compression.