Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Series of experiments and a detailed computational analysis has been performed to investigate the high strain rate behaviour of homostacked Al 6063-T6 and IS 1570 alloys. Split Hopkinson pressure bar technique was utilized to study the effect of high rate loading on the stress strain relationship of single, double, tri and quad layered/stacked specimens. Three different specimen aspect ratios 1, 0.75 and 0.5 were also evaluated for different strain rates. A 2 mm thick pulse shaper was employed in achieving dynamic stress equilibrium, a near constant strain rate and a high rise time as per requirements. After analyzing the results from the experiments it was observed that single and halved specimens showed a close match in both the elastic and plastic regions for aluminium alloy as well as for steel. In the case of Al 6063-T6, a nearly bi-linear nature of the constitutive curve was observed for single and halved specimens, which transformed into near tri-linear nature for tri and quad stacked specimens. The dynamic numerical analysis showed a good agreement between the numerical and experimental results for a single and halved specimen in the case of Al alloy. For steel, a close correlation was observed for all the four cases.
Czasopismo
Rocznik
Tom
Strony
1139--1151
Opis fizyczny
Bibliogr. 21 poz., rys., tab.
Twórcy
autor
- Indian Institute of Technology Delhi, Department of Applied Mechanics, New Delhi, India
autor
- Indian Institute of Technology Delhi, Department of Applied Mechanics, New Delhi, India
Bibliografia
- 1. Corran R.S.J., Shadbolt P.J., Ruiz C., 1983, Impact loading of platesan experimental investigation, International Journal of Impact Engineering, 1, 1, 3-22
- 2. Ellwood S., Griffiths L.J., Parry D.J., 1982, Materials testing at high constant strain rates, Journal of Physics E: Scientific Instruments, 15, 280-282
- 3. Engineers and Builders, 2015, Standard tools and techniques for dynamic characterization of materials, Design book, http://www.engineersandbuilders.com
- 4. Flores-Johnson E.A., Saleh M., Edwards L., 2011, Ballistic performance of multi-layered metallic plates impacted by a 7.62-mm APM2 projectile, International Journal of Impact Engineering, 38, 12, 1022-1032
- 5. Hartley R.S., Cloete T.J., Nurick G.N., 2007, An experimental assessment of friction effects in the split Hopkinson pressure bar using the ring compression test, International Journal of Impact Engineering, 34, 1705-1728
- 6. Jankowiak T., Rusinek A., Lodygowski T., 2011, Validation of the Klepaczko-Malinowski model for friction correction and recommendations on Split Hopkinson Pressure Bar, Finite Elements in Analysis and Design, 47, 10, 1191-1208
- 7. Jenq S.T., Sheu S.L., 1994, An experimental and numerical analysis for high strain rate compressional behaviour of 6061-O aluminium alloy, Computers and Structures, 52, 1, 27-34
- 8. Johnson G.R., Cook W.H., 1983, A constitutive model and data for metal subjected to large strains, high strain rates and high temperatures, Proceedings of the Seventh Symposium on Ballistics, The Hague, Netherlands
- 9. Khan A.S., Huang S., 1992, Experimental and theoretical study of mechanical behaviour of 1100 aluminium in the strain rate range 10−5 -104 s −1 , International Journal of Plasticity, 8, 4, 397-424
- 10. Kolsky H., 1949, An investigation of mechanical properties of materials at very high rates of loading, Proceedings of the Physical Society, B, 62, 11, 676-700
- 11. Li P., Siviour C.R., Petrinic N., 2009, The effect of strain rate, specimen geometry and lubrication on responses of aluminium AA2024 in uniaxial compression experiments, Experimental Mechanics, 49, 4, 587-593
- 12. Naghdabadi R., Ashrafi M.J., Arghavani J., 2012, Experimental and numerical investigation of pulse shaped split Hopkinson pressure bar test, Materials Science and Engineering A, 539, 285-293
- 13. Nia A.A., Hoseini G.R., 2011, Experimental study of perforation of multi-layered targets by hemispherical-nosed projectiles, Materials and Design, 32, 2, 1057-1065
- 14. Pankow M., Attard C., Waas A.M., 2009, Specimen size and shape effect in split Hopkinson pressure bar testing, Journal of Strain Analysis for Engineering Design, 44, 8, 689-698
- 15. Radin J., Goldsmith W., 1988, Normal projectile penetration and perforation of layered targets, International Journal of Impact Engineering, 7, 2, 229-259
- 16. Sato Y.S., Kokawa H., Enomoto M., Jogan S., 1999, Microstructural evolution of 6063 aluminum during friction-stir welding, Metallurgical and Materials Transactions A, 30, 9, 2429-2437
- 17. Walley S.M., Radford D.D., Chapman D.J., 2006, The effect of aspect ratio on the compressive high rate deformation of three metallic alloys, Journal de Physique IV, 134, 851-856
- 18. Woldesenbet E., Vinson J.R., 1999, Specimen geometry effects on high strain rate testing of graphite/epoxy composites, AIAA Journal, 37, 9, 1102-1106
- 19. Wu X.J., Gorham D.A., 1997, Stress equilibrium in the split Hopkinson pressure bar test, Journal de Physique IV, 7, C3, 91-96
- 20. Ye T., Li L., Guo P., Xiao G., Chen Z., 2016, Effect of aging treatment on the microstructure and flow behavior of 6063 aluminum alloy compressed over a wide range of strain rate, International Journal of Impact Engineering, 90, 72-80
- 21. Zhong W.Z., Rusinek A., Jankowiak T., Abed F., Bernier R., Sutter G., 2015, Influence of interfacial friction and specimen configuration in Split Hopkinson Pressure Bar system, Tribology International, 90, 1-14
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c520f5f9-db1d-4cac-9080-a973fc9979b0