Influence of Strain History on Dynamic Strain Localization and Stress State During High-Rate Tensile Loading of Titanium Alloys: Experiments, Modeling, and Analytical Methods

Govind Gour; Daniel Thomson; Karthik Ram Ramakrishnan; David Townsend; Nik Petrinic; Antonio Pellegrino

doi:10.1115/1.4056136

Influence of Strain History on Dynamic Strain Localization and Stress State During High-Rate Tensile Loading of Titanium Alloys: Experiments, Modeling, and Analytical Methods

Govind Gour^*, Daniel Thomson, Karthik Ram Ramakrishnan, David Townsend, Nik Petrinic, Antonio Pellegrino

^*Corresponding author for this work

Bristol Composites Institute

Research output: Contribution to journal › Article (Academic Journal) › peer-review

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Abstract

The determination of the mechanical response of engineering materials subjected to high loading rates plays an important role in determining their performance and application. The high strain-rate tensile response of metals is usually investigated by means of the split-Hopkinson tension bar (SHTB) apparatus. The interpretation of the obtained results is, however, subjected to analogous stress and strain uniformity challenges present during quasi-static tensile experiments. Beyond the onset of necking, strains cease to be uniform along the gauge length and localize around the necking zone. Consequently, the
nominal strain rate underestimates the effective strain rate experienced by the material. The analysis of the effective strain rate and stress state beyond the onset of necking has received considerable attention in the literature. Several research efforts have focused on the optimization of the geometry of specimens to be employed for the characterization of the dynamic tensile response using the SHTB. The present work investigates, systematically, the effects of strain history and adiabatic heating on the stress state during dynamic loading. A series of monotonic and various strain history experiments were conducted
and analyzed. The diameter evolution, effective strain rate, and temperature histories were measured for all conducted experiments. Numerical simulations were carried out to examine the stress state during strain localization and to accurately reproduce engineering and local thermos-mechanical variables. The effectiveness of existing post-necking corrections for high-rate experiments is assessed. A modified post-necking correlation taking into account the effects of adiabatically induced thermal softening is proposed.

Original language	English
Article number	021005
Number of pages	17
Journal	Journal of Applied Mechanics
Volume	90
Issue number	2
Early online date	18 Nov 2022
DOIs	https://doi.org/10.1115/1.4056136
Publication status	Published - 1 Feb 2023

Bibliographical note

Funding Information:
The authors would like to thank Rolls-Royce plc and the EPSRC for the support under the Prosperity Partnership Grant\Cornerstone: Mechanical Engineering Science to Enable Aero Propulsion Futures, Grant Ref: EP/R004951/1. The authors would also like to thank Mr. Stuart Carter, Mr. Jeffrey Fullerton, Mr. Peter Tantrum, and Mr. Derek Robinson for manufacturing the specimens and for the helpful suggestions, Mrs. Karen Bamford for her continuous support, and Dr. Longhui Zhang for the useful technical discussions.

Publisher Copyright:
Copyright © 2022 by ASME.

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title = "Influence of Strain History on Dynamic Strain Localization and Stress State During High-Rate Tensile Loading of Titanium Alloys: Experiments, Modeling, and Analytical Methods",

abstract = "The determination of the mechanical response of engineering materials subjected to high loading rates plays an important role in determining their performance and application. The high strain-rate tensile response of metals is usually investigated by means of the split-Hopkinson tension bar (SHTB) apparatus. The interpretation of the obtained results is, however, subjected to analogous stress and strain uniformity challenges present during quasi-static tensile experiments. Beyond the onset of necking, strains cease to be uniform along the gauge length and localize around the necking zone. Consequently, the nominal strain rate underestimates the effective strain rate experienced by the material. The analysis of the effective strain rate and stress state beyond the onset of necking has received considerable attention in the literature. Several research efforts have focused on the optimization of the geometry of specimens to be employed for the characterization of the dynamic tensile response using the SHTB. The present work investigates, systematically, the effects of strain history and adiabatic heating on the stress state during dynamic loading. A series of monotonic and various strain history experiments were conducted and analyzed. The diameter evolution, effective strain rate, and temperature histories were measured for all conducted experiments. Numerical simulations were carried out to examine the stress state during strain localization and to accurately reproduce engineering and local thermos-mechanical variables. The effectiveness of existing post-necking corrections for high-rate experiments is assessed. A modified post-necking correlation taking into account the effects of adiabatically induced thermal softening is proposed.",

author = "Govind Gour and Daniel Thomson and Ramakrishnan, \{Karthik Ram\} and David Townsend and Nik Petrinic and Antonio Pellegrino",

note = "Funding Information: The authors would like to thank Rolls-Royce plc and the EPSRC for the support under the Prosperity Partnership Grant\textbackslash{}Cornerstone: Mechanical Engineering Science to Enable Aero Propulsion Futures, Grant Ref: EP/R004951/1. The authors would also like to thank Mr. Stuart Carter, Mr. Jeffrey Fullerton, Mr. Peter Tantrum, and Mr. Derek Robinson for manufacturing the specimens and for the helpful suggestions, Mrs. Karen Bamford for her continuous support, and Dr. Longhui Zhang for the useful technical discussions. Publisher Copyright: Copyright {\textcopyright} 2022 by ASME.",

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doi = "10.1115/1.4056136",

language = "English",

volume = "90",

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Influence of Strain History on Dynamic Strain Localization and Stress State During High-Rate Tensile Loading of Titanium Alloys: Experiments, Modeling, and Analytical Methods. / Gour, Govind; Thomson, Daniel; Ramakrishnan, Karthik Ram et al.
In: Journal of Applied Mechanics, Vol. 90, No. 2, 021005, 01.02.2023.

Research output: Contribution to journal › Article (Academic Journal) › peer-review

TY - JOUR

T1 - Influence of Strain History on Dynamic Strain Localization and Stress State During High-Rate Tensile Loading of Titanium Alloys

T2 - Experiments, Modeling, and Analytical Methods

AU - Gour, Govind

AU - Thomson, Daniel

AU - Ramakrishnan, Karthik Ram

AU - Townsend, David

AU - Petrinic, Nik

AU - Pellegrino, Antonio

N1 - Funding Information: The authors would like to thank Rolls-Royce plc and the EPSRC for the support under the Prosperity Partnership Grant\Cornerstone: Mechanical Engineering Science to Enable Aero Propulsion Futures, Grant Ref: EP/R004951/1. The authors would also like to thank Mr. Stuart Carter, Mr. Jeffrey Fullerton, Mr. Peter Tantrum, and Mr. Derek Robinson for manufacturing the specimens and for the helpful suggestions, Mrs. Karen Bamford for her continuous support, and Dr. Longhui Zhang for the useful technical discussions. Publisher Copyright: Copyright © 2022 by ASME.

PY - 2023/2/1

Y1 - 2023/2/1

N2 - The determination of the mechanical response of engineering materials subjected to high loading rates plays an important role in determining their performance and application. The high strain-rate tensile response of metals is usually investigated by means of the split-Hopkinson tension bar (SHTB) apparatus. The interpretation of the obtained results is, however, subjected to analogous stress and strain uniformity challenges present during quasi-static tensile experiments. Beyond the onset of necking, strains cease to be uniform along the gauge length and localize around the necking zone. Consequently, the nominal strain rate underestimates the effective strain rate experienced by the material. The analysis of the effective strain rate and stress state beyond the onset of necking has received considerable attention in the literature. Several research efforts have focused on the optimization of the geometry of specimens to be employed for the characterization of the dynamic tensile response using the SHTB. The present work investigates, systematically, the effects of strain history and adiabatic heating on the stress state during dynamic loading. A series of monotonic and various strain history experiments were conducted and analyzed. The diameter evolution, effective strain rate, and temperature histories were measured for all conducted experiments. Numerical simulations were carried out to examine the stress state during strain localization and to accurately reproduce engineering and local thermos-mechanical variables. The effectiveness of existing post-necking corrections for high-rate experiments is assessed. A modified post-necking correlation taking into account the effects of adiabatically induced thermal softening is proposed.

AB - The determination of the mechanical response of engineering materials subjected to high loading rates plays an important role in determining their performance and application. The high strain-rate tensile response of metals is usually investigated by means of the split-Hopkinson tension bar (SHTB) apparatus. The interpretation of the obtained results is, however, subjected to analogous stress and strain uniformity challenges present during quasi-static tensile experiments. Beyond the onset of necking, strains cease to be uniform along the gauge length and localize around the necking zone. Consequently, the nominal strain rate underestimates the effective strain rate experienced by the material. The analysis of the effective strain rate and stress state beyond the onset of necking has received considerable attention in the literature. Several research efforts have focused on the optimization of the geometry of specimens to be employed for the characterization of the dynamic tensile response using the SHTB. The present work investigates, systematically, the effects of strain history and adiabatic heating on the stress state during dynamic loading. A series of monotonic and various strain history experiments were conducted and analyzed. The diameter evolution, effective strain rate, and temperature histories were measured for all conducted experiments. Numerical simulations were carried out to examine the stress state during strain localization and to accurately reproduce engineering and local thermos-mechanical variables. The effectiveness of existing post-necking corrections for high-rate experiments is assessed. A modified post-necking correlation taking into account the effects of adiabatically induced thermal softening is proposed.

U2 - 10.1115/1.4056136

DO - 10.1115/1.4056136

M3 - Article (Academic Journal)

SN - 0021-8936

VL - 90

JO - Journal of Applied Mechanics

JF - Journal of Applied Mechanics

IS - 2

M1 - 021005

ER -

Influence of Strain History on Dynamic Strain Localization and Stress State During High-Rate Tensile Loading of Titanium Alloys: Experiments, Modeling, and Analytical Methods

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