A benchmark testing technique to characterize the stress-strain relationship in materials based on the spalling test and a photomechanical method
A benchmark testing technique to characterize the stress-strain relationship in materials based on the spalling test and a photomechanical method
The experimental testing of concrete and other brittle materials under high-strain rate tensile loading remains a major issue in many research fields and industrial applications. Among the experimental methods, the spalling technique provides a major advantage as it does not rely on a static mechanical balance of the sample. A short compressive pulse transmitted to the sample reflects from the rear free surface as a tensile pulse leading to sample tensile fracturing. However, the classic processing (i.e. Novikov's acoustic approximation) based on the measurement of the sample rear face velocity profile, relies on strong assumptions that can lead to an over-estimation of the material tensile strength. A new processing technique was proposed by Pierron and Forquin (2012 Strain 48 388–405) to derive the stress field and apparent Young's modulus using only data from an ultra-high speed camera. This purely inertial method is based on the time resolved measurement of axial displacement fields and the virtual fields methods (VFM). However, the measurement accuracy as well as uncertainty remains to be studied in more detail and better understood. In the present work, a series of spalling tests have been performed with a sample made of aluminium alloy behaving linearly elastic. Such test allows investigating a possible influence of several testing parameters (e.g. interframe time, lens focusing, number of pixels per period...), processing parameters (mainly the levels of spatial and temporal smoothing for regularization) as well as the influence of the camera sensor technology. The results are compared to data from strain gauges and to the expected Young's modulus and stress–strain response of the tested aluminium alloy, so the accuracy of measurements is evaluated. Finally, the spalling set-up applied to a sample of well-known mechanical properties appears to be a good benchmark to assess the quality of stress versus strain measurements based on photomechanical methods.
Virtual fields method, spalling, dynamic testing, concrete, grid measurement, high-speed imaging
Forquin, Pascal
b93d9562-887e-4e3c-9821-0ecaa351f0c5
Lukic, Bratislav
3c9f7dfe-c006-4083-b10c-32216efb46dc
Saletti, Dominique
65604991-cc6f-4a7b-8d5e-b52890067430
Sallier, Laurent
ff1d2b09-443c-437e-8a59-2481a02056f9
Pierron, Fabrice
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
17 September 2019
Forquin, Pascal
b93d9562-887e-4e3c-9821-0ecaa351f0c5
Lukic, Bratislav
3c9f7dfe-c006-4083-b10c-32216efb46dc
Saletti, Dominique
65604991-cc6f-4a7b-8d5e-b52890067430
Sallier, Laurent
ff1d2b09-443c-437e-8a59-2481a02056f9
Pierron, Fabrice
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
Forquin, Pascal, Lukic, Bratislav, Saletti, Dominique, Sallier, Laurent and Pierron, Fabrice
(2019)
A benchmark testing technique to characterize the stress-strain relationship in materials based on the spalling test and a photomechanical method.
Measurement Science and Technology, 30 (12), [125006].
(doi:10.1088/1361-6501/ab35c8).
Abstract
The experimental testing of concrete and other brittle materials under high-strain rate tensile loading remains a major issue in many research fields and industrial applications. Among the experimental methods, the spalling technique provides a major advantage as it does not rely on a static mechanical balance of the sample. A short compressive pulse transmitted to the sample reflects from the rear free surface as a tensile pulse leading to sample tensile fracturing. However, the classic processing (i.e. Novikov's acoustic approximation) based on the measurement of the sample rear face velocity profile, relies on strong assumptions that can lead to an over-estimation of the material tensile strength. A new processing technique was proposed by Pierron and Forquin (2012 Strain 48 388–405) to derive the stress field and apparent Young's modulus using only data from an ultra-high speed camera. This purely inertial method is based on the time resolved measurement of axial displacement fields and the virtual fields methods (VFM). However, the measurement accuracy as well as uncertainty remains to be studied in more detail and better understood. In the present work, a series of spalling tests have been performed with a sample made of aluminium alloy behaving linearly elastic. Such test allows investigating a possible influence of several testing parameters (e.g. interframe time, lens focusing, number of pixels per period...), processing parameters (mainly the levels of spatial and temporal smoothing for regularization) as well as the influence of the camera sensor technology. The results are compared to data from strain gauges and to the expected Young's modulus and stress–strain response of the tested aluminium alloy, so the accuracy of measurements is evaluated. Finally, the spalling set-up applied to a sample of well-known mechanical properties appears to be a good benchmark to assess the quality of stress versus strain measurements based on photomechanical methods.
Text
ArticleMST-PF-BL-DS-LS-FP_11july2019
- Accepted Manuscript
More information
Accepted/In Press date: 25 July 2019
Published date: 17 September 2019
Keywords:
Virtual fields method, spalling, dynamic testing, concrete, grid measurement, high-speed imaging
Identifiers
Local EPrints ID: 436289
URI: http://eprints.soton.ac.uk/id/eprint/436289
ISSN: 0957-0233
PURE UUID: 97036219-4fe2-43c9-a571-d19d068afbee
Catalogue record
Date deposited: 06 Dec 2019 17:30
Last modified: 17 Mar 2024 05:07
Export record
Altmetrics
Contributors
Author:
Pascal Forquin
Author:
Bratislav Lukic
Author:
Dominique Saletti
Author:
Laurent Sallier
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
