Experimental and numerical investigations on the use of polymer Hopkinson pressure bars

John J. Harrigan; Bright Ahonsi; Elisavet Palamidi; Steve R. Reid

doi:10.1098/rsta.2013.0201

Experimental and numerical investigations on the use of polymer Hopkinson pressure bars

John J. Harrigan^* (Corresponding Author), Bright Ahonsi, Elisavet Palamidi, Steve R. Reid

^*Corresponding author for this work

University of Manchester

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

Split Hopkinson pressure bar (SHPB) testing has traditionally been carried out using metal bars. For testing low stiffness materials such as rubbers or low strength materials such as low density cellular solids considered primarily herein, there are many advantages to replacing the metal bars with polymer bars. An investigation of a number of aspects associated with the accuracy of SHPB testing of these materials is reported. Test data are used to provide qualitative comparisons of accuracy using different bar materials and wave-separation techniques. Sample results from SHPB tests are provided for balsa, Rohacell foam and hydroxyl-terminated polybutadiene. The techniques used are verified by finite-element (FE) analysis. Experimentally, the material properties of the bars are determined from impact tests in the form of a complex elastic modulus without curve fitting to a rheological model. For the simulations, a rheological model is used to define the bar properties by curve fitting to the experimentally derived properties. Wave propagation in a polymer bar owing to axial impact of a steel bearing ball is simulated. The results indicate that the strain histories can be used to determine accurately the viscoelastic properties of polymer bars. An FE model of the full viscoelastic SHPB set-up is then used to simulate tests on hyperelastic materials.

Original language	English
Article number	20130201
Number of pages	16
Journal	Philosophical Transactions of the Royal Society A: Mathematical, Physical & Engineering Sciences
Volume	372
Issue number	2023
DOIs	https://doi.org/10.1098/rsta.2013.0201
Publication status	Published - 28 Aug 2014

Bibliographical note

J.J.H. and B.A. gratefully acknowledge the financial support of QinetiQ and EPSRC through the industrial CASE scheme. J.J.H. is grateful for the support provided through the LRF Centre. LRF, a UK registered charity and sole shareholder of Lloyd's Register Group Ltd, invests in science, engineering and technology for public benefit, worldwide.

Keywords

finite element
stress wave
viscoelasticity
Hopkinson pressure bar

Access to Document

10.1098/rsta.2013.0201Licence: Unspecified

Cite this

Experimental and numerical investigations on the use of polymer Hopkinson pressure bars. / Harrigan, John J. (Corresponding Author); Ahonsi, Bright; Palamidi, Elisavet et al.
In: Philosophical Transactions of the Royal Society A: Mathematical, Physical & Engineering Sciences, Vol. 372, No. 2023, 20130201, 28.08.2014.

Research output: Contribution to journal › Article › peer-review

@article{39319db51bf245a984469c20f76953c0,

title = "Experimental and numerical investigations on the use of polymer Hopkinson pressure bars",

abstract = "Split Hopkinson pressure bar (SHPB) testing has traditionally been carried out using metal bars. For testing low stiffness materials such as rubbers or low strength materials such as low density cellular solids considered primarily herein, there are many advantages to replacing the metal bars with polymer bars. An investigation of a number of aspects associated with the accuracy of SHPB testing of these materials is reported. Test data are used to provide qualitative comparisons of accuracy using different bar materials and wave-separation techniques. Sample results from SHPB tests are provided for balsa, Rohacell foam and hydroxyl-terminated polybutadiene. The techniques used are verified by finite-element (FE) analysis. Experimentally, the material properties of the bars are determined from impact tests in the form of a complex elastic modulus without curve fitting to a rheological model. For the simulations, a rheological model is used to define the bar properties by curve fitting to the experimentally derived properties. Wave propagation in a polymer bar owing to axial impact of a steel bearing ball is simulated. The results indicate that the strain histories can be used to determine accurately the viscoelastic properties of polymer bars. An FE model of the full viscoelastic SHPB set-up is then used to simulate tests on hyperelastic materials.",

keywords = "finite element, stress wave, viscoelasticity, Hopkinson pressure bar",

author = "Harrigan, {John J.} and Bright Ahonsi and Elisavet Palamidi and Reid, {Steve R.}",

note = "J.J.H. and B.A. gratefully acknowledge the financial support of QinetiQ and EPSRC through the industrial CASE scheme. J.J.H. is grateful for the support provided through the LRF Centre. LRF, a UK registered charity and sole shareholder of Lloyd's Register Group Ltd, invests in science, engineering and technology for public benefit, worldwide.",

year = "2014",

month = aug,

day = "28",

doi = "10.1098/rsta.2013.0201",

language = "English",

volume = "372",

journal = "Philosophical Transactions of the Royal Society A: Mathematical, Physical & Engineering Sciences",

issn = "1364-503X",

publisher = "Royal Society Publishing",

number = "2023",

}

TY - JOUR

T1 - Experimental and numerical investigations on the use of polymer Hopkinson pressure bars

AU - Harrigan, John J.

AU - Ahonsi, Bright

AU - Palamidi, Elisavet

AU - Reid, Steve R.

N1 - J.J.H. and B.A. gratefully acknowledge the financial support of QinetiQ and EPSRC through the industrial CASE scheme. J.J.H. is grateful for the support provided through the LRF Centre. LRF, a UK registered charity and sole shareholder of Lloyd's Register Group Ltd, invests in science, engineering and technology for public benefit, worldwide.

PY - 2014/8/28

Y1 - 2014/8/28

N2 - Split Hopkinson pressure bar (SHPB) testing has traditionally been carried out using metal bars. For testing low stiffness materials such as rubbers or low strength materials such as low density cellular solids considered primarily herein, there are many advantages to replacing the metal bars with polymer bars. An investigation of a number of aspects associated with the accuracy of SHPB testing of these materials is reported. Test data are used to provide qualitative comparisons of accuracy using different bar materials and wave-separation techniques. Sample results from SHPB tests are provided for balsa, Rohacell foam and hydroxyl-terminated polybutadiene. The techniques used are verified by finite-element (FE) analysis. Experimentally, the material properties of the bars are determined from impact tests in the form of a complex elastic modulus without curve fitting to a rheological model. For the simulations, a rheological model is used to define the bar properties by curve fitting to the experimentally derived properties. Wave propagation in a polymer bar owing to axial impact of a steel bearing ball is simulated. The results indicate that the strain histories can be used to determine accurately the viscoelastic properties of polymer bars. An FE model of the full viscoelastic SHPB set-up is then used to simulate tests on hyperelastic materials.

AB - Split Hopkinson pressure bar (SHPB) testing has traditionally been carried out using metal bars. For testing low stiffness materials such as rubbers or low strength materials such as low density cellular solids considered primarily herein, there are many advantages to replacing the metal bars with polymer bars. An investigation of a number of aspects associated with the accuracy of SHPB testing of these materials is reported. Test data are used to provide qualitative comparisons of accuracy using different bar materials and wave-separation techniques. Sample results from SHPB tests are provided for balsa, Rohacell foam and hydroxyl-terminated polybutadiene. The techniques used are verified by finite-element (FE) analysis. Experimentally, the material properties of the bars are determined from impact tests in the form of a complex elastic modulus without curve fitting to a rheological model. For the simulations, a rheological model is used to define the bar properties by curve fitting to the experimentally derived properties. Wave propagation in a polymer bar owing to axial impact of a steel bearing ball is simulated. The results indicate that the strain histories can be used to determine accurately the viscoelastic properties of polymer bars. An FE model of the full viscoelastic SHPB set-up is then used to simulate tests on hyperelastic materials.

KW - finite element

KW - stress wave

KW - viscoelasticity

KW - Hopkinson pressure bar

U2 - 10.1098/rsta.2013.0201

DO - 10.1098/rsta.2013.0201

M3 - Article

SN - 1364-503X

VL - 372

JO - Philosophical Transactions of the Royal Society A: Mathematical, Physical & Engineering Sciences

JF - Philosophical Transactions of the Royal Society A: Mathematical, Physical & Engineering Sciences

IS - 2023

M1 - 20130201

ER -

Experimental and numerical investigations on the use of polymer Hopkinson pressure bars

Abstract

Bibliographical note

Keywords

Access to Document

Fingerprint

Cite this