Beyond Hopkinson's bar
Beyond Hopkinson's bar
In order to perform experimental identification of high strain rate material models, engineers have only a very limited toolbox based on test procedures developed decades ago. The best example is the so-called split Hopkinson pressure bar based on the bar concept introduced 100 years ago by Bertram Hopkinson to measure blast pulses. The recent advent of full-field deformation measurements using imaging techniques has allowed novel approaches to be developed and exciting new testing procedures to be imagined for the first time. One can use this full-field information in conjunction with efficient numerical inverse identification tools such as the virtual fields method (VFM) to identify material parameters at high rates. The underpinning novelty is to exploit the inertial effects developed in high strain rate loading. This paper presents results from a new inertial impact test to obtain stress–strain curves at high strain rates (here, up to 3000 s−1). A quasi-isotropic composite specimen is equipped with a grid and images are recorded with the new HPV-X camera from Shimadzu at 5 Mfps and the SIMX16 camera from Specialised Imaging at 1 Mfps. Deformation, strain and acceleration fields are then input into the VFM to identify the stiffness parameters with unprecedented quality.
Pierron, F.
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
Zhu, H.
56de08ce-886f-4d04-bbc5-ee175ce014ae
Siviour, C.
4d607d0d-b85e-423f-95e4-f35bb73eb4bd
28 July 2014
Pierron, F.
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
Zhu, H.
56de08ce-886f-4d04-bbc5-ee175ce014ae
Siviour, C.
4d607d0d-b85e-423f-95e4-f35bb73eb4bd
Pierron, F., Zhu, H. and Siviour, C.
(2014)
Beyond Hopkinson's bar.
Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 372 (2023), [20130195].
(doi:10.1098/rsta.2013.0195).
Abstract
In order to perform experimental identification of high strain rate material models, engineers have only a very limited toolbox based on test procedures developed decades ago. The best example is the so-called split Hopkinson pressure bar based on the bar concept introduced 100 years ago by Bertram Hopkinson to measure blast pulses. The recent advent of full-field deformation measurements using imaging techniques has allowed novel approaches to be developed and exciting new testing procedures to be imagined for the first time. One can use this full-field information in conjunction with efficient numerical inverse identification tools such as the virtual fields method (VFM) to identify material parameters at high rates. The underpinning novelty is to exploit the inertial effects developed in high strain rate loading. This paper presents results from a new inertial impact test to obtain stress–strain curves at high strain rates (here, up to 3000 s−1). A quasi-isotropic composite specimen is equipped with a grid and images are recorded with the new HPV-X camera from Shimadzu at 5 Mfps and the SIMX16 camera from Specialised Imaging at 1 Mfps. Deformation, strain and acceleration fields are then input into the VFM to identify the stiffness parameters with unprecedented quality.
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Paper_RSProc_Hop_2013.pdf
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e-pub ahead of print date: 28 July 2014
Published date: 28 July 2014
Organisations:
Engineering Mats & Surface Engineerg Gp
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Local EPrints ID: 367368
URI: http://eprints.soton.ac.uk/id/eprint/367368
ISSN: 1364-503X
PURE UUID: 1d216a1c-8221-4907-a1b4-4ebe163585b6
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Date deposited: 22 Aug 2014 14:21
Last modified: 15 Mar 2024 03:35
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Author:
H. Zhu
Author:
C. Siviour
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