Numerical investigation of System Ringing and Stress Oscillations in High Speed Tensile Test on Polymers
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Author(s)
Abstract
The Finite Element (F.E.) analysis of a grip system of a servo hydraulic machine used for high speed tensile testing of polymers is here presented. State-of-the- art dynamometers use a slack adaptor to allow the machine to accelerate, in order to reach the nominal tensile speed before the load is applied, so that the entire test is conducted at constant speed. In this case the sudden application of the load causes the onset of stress waves that can excite the system, causing it to oscillate at its natural frequency. This phenomenon, called “system ringing”, is here examined through the analysis of the frequencies characterizing the oscillations in the initial transient of the tensile test. It will be shown that this analysis can be a suitable tool for assessing what is the maximum strain rate achievable with a given equipment. We also show that the stress oscillations contain information that can be related to material properties and, consequently, can be used for their measurement through simple spectrum analyses. Some examples are reported for an easy determination of the Young modulus of a Polypropylene (PP) based compounds from the Fast Fourier Transform (FFT) of the force signal.
Keywords
polymers; high speed tensile tests; system ringing; FFT; strain rate
Cite this paper
M.Nutini, D.Sinnone, M.Vitali,
Numerical investigation of System Ringing and Stress Oscillations in High Speed Tensile Test on Polymers
, SCIREA Journal of Mechanical Engineering.
Volume 3, Issue 1, February 2020 | PP. 1-19.
References
[ 1 ] | Xiao X., “Dynamic tensile testing of plastic materials”, Polymer testing 27 (2008), 164-178 |
[ 2 ] | Yang X. Et al., “A combined Theoretical/Experimental Approach for Reducing Ringing Artifacts in Low Dynamic Testing with Servo-hydraulic Load Frames”, Experimental Mechanics, DOI 10.1007/s11340-014-9850-x |
[ 3 ] | Zhu D. et al., “Modal Analysis of a Servo-Hydraulic High Speed Machine and its Application to Dynamic Tensile Testing at an Intermediate Strain Rate”, Experimental Mechanics, DOI 10.1007/s11340-010-9443-2 |
[ 4 ] | Xiao X., “Analysis of Dynamic Tensile Testing”, Proceedings of the X1th International Congress and Exposition, Orlando 2008 |
[ 5 ] | Spronk S.W.F. et al., “Dynamic Tensile Testing of Brittle Composites Using a Hydraulic Pulse Machine: Stress-Strain Synchronization and Strain Rate Limits”, ICEM Proceedings, 2, 405, DOI: 10.3390/ICEM18-05274, 2018 |
[ 6 ] | Fitoussi et al., “Experimental methodology for high strain-rates tensile behavior analysis of polymer matrix composites”, Composites Science and Technology 65 (2005), pp 2174-2188 |
[ 7 ] | Dioh N. et al., “The high strain rate behavior of polymers”, Journal de Physique IV, Colloque C8, supplement au Journal de Physique III, Vol. 4 , Sept. 1994 |
[ 8 ] | Surface Vehicles Recommended Practice- High Strain rate Tensile Testing of Polymers, SAE Technical Standard J2749, 2008 |
[ 9 ] | Fang X. et al., “A new Tensile Test Sample Geometry for Oscillation-free Determination of Material Properties at High Strain Rate”, BSSM 14th Conference, Belfast, 2019 |
[ 10 ] | Cheresh M.C. et al., “Instrumented impact data interpretation, in: Kessler et al., Instrumented Impact Testing of Plastics and Composite Materials: a Symposium,” ASTM International, 1987, pp. 9-23 |
[ 11 ] | Quin Z. et al., “System Ringing in Impact test Triggered by Upper-and Lower Yield Points of Materials”, Int. J. impact Engineering 000 (2017), http://dx.doi.org/10.1016/j.ijimpeng.2017.04.020 |
[ 12 ] | Grams et al., “New Developments in Material Testing at Very High Strain Rates”, 12th European Ls-dyna Conference, Koblenz, Germany, 2019 |
[ 13 ] | Wen H. et al, “Hanning Self-Convolution Window and Its Application to Harmonic Analysis”, Sci China Ser E-Tech Sci, Feb 2009, pp. 467-476 |
[ 14 ] | Sahraoui S. et al, “Analysis of Load Oscillations I Instrumented Impact testing”, Engineering fracture mechanics Vol. 60, No. 4, pp. 437-446, 1998 |
[ 15 ] | Ashby M.F., Jones D.R.H., Engineering Materials, Elsevier, 2012 |
[ 16 ] | ABAQUS User’s Manual (2018) |
[ 17 ] | www.LyondellBasell.com |
[ 18 ] | Georgi H., The Physics of Waves, Online Edition, 2015, https://www.people.fas.harvard.edu/~hgeorgi/onenew.pdf |