Publication: Modeling and design of SHPB to characterize brittle materials under compression for high strain rates
Loading...
Identifiers
Publication date
2020-01-01
Defense date
Advisors
Tutors
Journal Title
Journal ISSN
Volume Title
Publisher
MDPI
Impact
Export
Abstract
This paper presents an analytical prediction coupled with numerical simulations of a split Hopkinson pressure bar (SHPB) that could be used during further experiments to measure the dynamic compression strength of concrete. The current study combines experimental, modeling and numerical results, permitting an inverse method by which to validate measurements. An analytical prediction is conducted to determine the waves propagation present in SHPB using a one-dimensional theory and assuming a strain rate dependence of the material strength. This method can be used by designers of new SPHB experimental setups to predict compressive strength or strain rates reached during tests, or to check the consistencies of predicted results. Numerical simulation results obtained using LS-DYNA finite element software are also presented in this paper, and are used to compare the predictions with the analytical results. This work focuses on an SPHB setup that can accurately identify the strain rate sensitivities of concrete or brittle materials.
Description
Keywords
Concrete, Simulation, Brittle materials, Dynamic compression, Split hopkinson pressure bars (sphb)
Bibliographic citation
Jankowiak, T., Rusinek, A., & Voyiadjis, G. Z. (2020). Modeling and design of SHPB to characterize brittle materials under compression for high strain rates. Materials, 13(9), 2191.