On the development of a high strain-rate tensile testing method for thin low-impedance materials.

• An attempt to characterize thin, low impedance paper at various high strain-rates. • The creation of a digital twin of the physical Split Hopkinson Test bench. • To demonstrate that there can be distortions of the transmitted measuring signal. This work deals with the high strain-rate characterization of paper under uniaxial tension using a Split Hopkinson test bench. An aluminum bar system featuring a highly sensitive hollow transmission bar was used. Paper tests were performed in a strain-rate range between approximately 60 s−1 and 210 s−1. The experimental tests showed that the breaking strength appears to decrease with increasing strain-rate. To verify these results, a digital twin of both the paper specimen and the entire test rig was created in an explicit Finite Element method environment. The numerical model was then used to perform a parameter study with different types of transmission bars. It was shown that the system is quite sensitive to additional masses caused by the specimen fixtures, as well as to drastic reductions in the cross section of the transmission bar. As a result, the transmitted measuring signal can be distorted and may need to be corrected using the digital twin. [ABSTRACT FROM AUTHOR]