Gépészeti és járműmérnöki tudományok

The Influence of the Boundary Conditions on the Buckling of Thin-walled Cans during Manufacturing

Megjelent:
2023-04-10
Szerző
Megtekintés
Kulcsszavak
Licenc

Copyright (c) 2023 Dávid Gönczi

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Hogyan hivatkozzuk
Kiválasztott formátum: APA
Gönczi, D. (2023). The Influence of the Boundary Conditions on the Buckling of Thin-walled Cans during Manufacturing. International Journal of Engineering and Management Sciences, 7(4), 41-50. https://doi.org/10.21791/IJEMS.2022.4.4.
Beküldött 2022-11-10
Elfogadott 2023-01-12
Publikált 2023-04-10
Absztrakt

In this paper the effect of the boundary conditions on the stability of thin-walled aerosol cans under axial pressure is investigated. The main objective is to outline the main characteristics of this highly nonlinear mechanical problem and to present methods to simulate the buckling of cans with different boundary conditions. Due to the numerical difficulties coming from the contact between the can and different components of the machines, the effect of the different supports of the can is investigated on the crushing (or buckling) force at which the loss of stability occurs. The commercial finite element software Abaqus is used to solve the problems and to present the efficiency of FE codes in the design process of cans.

Hivatkozások
  1. Reddy, J. N. (2006) ‘Theory and Analysis of Elastic Plates and Shells’. CRC Press.
  2. Chapelle, D., Bathe, C. J. (2011) ‘The Finite Element Analysis of Shells - Fundamentals. 2nd edition’, Springer.
  3. Hardy, S. J., Abdusslam, R. M. (2007) ‘Finite element modelling of the extrusion process for aluminium aerosol cans’, Proc. IMechE, Part L, J. Materials: Design and Applications, 221, pp. 265-274. https://doi.org/10.1243/14644207JMDA153
  4. Belblidia, F., Corft, N., Hardy, S. J., Shakespeare, V., Chambers, R. (2013) ‘Simulation based aerosol can design under pressure and buckling loads and comparison with experimental trials’, Materials and Design, 52, pp. 214-224. https://doi.org/10.1016/j.matdes.2013.05.041
  5. Belblidia, F., Corft, N., Hardy, S. J. , Bould, D. C. , Sienz, J. (2014) ‘Aerosol cans under pressure and buckling loads’, Sustainable Design and Manufacturing, 1, pp. 13-17.
  6. Folle, L.F., Netto, S.E.S., Schaeffer, L. (2008) ‘Analysis of the manufacturing process of beverage cans using aluminum alloy’, Journal of Material Processing Technology, 205, pp. 347-352. https://doi.org/10.1016/j.jmatprotec.2007.11.249
  7. Takeutshi, H. (1993) ‘Numerical simulation technology for lightweight aluminium can’. Journal of Material Processing Technology, 38, pp. 675-687. https://doi.org/10.1016/0924- 0136(93)90043-6
  8. Gönczi, D. (2020) ’Finite element investigation in the forming process of aluminium aerosol cans’, Acta Technica Corviniensis – Bulletin of Engineering, 13(4), pp. 19-22.
  9. Kiss, L. P. (2020) ‘Nonlinear stability analysis of FGM shallow arches under an arbitrary concentrated radial force’, International Journal of Mechanics and Materials in Design, 16 (1), pp. 91-108.
  10. https://doi.org/10.1007/s10999-019-09460-2
  11. Sofiyev, A. H., Hui, D. (2019) ‘On the vibration and stability of FGM cylindrical shells under external pressures with mixed boundary conditions by using FOSDT’. Thin-Walled Structures, 134, pp. 419-427. https://doi.org/10.1016/j.tws.2018.10.018
  12. Prabu, B., Raviprakash, A.V., Venkatraman, A. (2009) ‘Neighbourhood effect of two short dents on buckling behavior of thin short stainless steel cylindrical shells’. International Journal of Computer Aided Engineering & Technology, 4(12). https://doi.org/10.1504/IJCAET.2012.045654
  13. Schneider, W. (2006) ‘Stimulating equivalent geometrical imperfections for the numerical buckling strength verification of axially compressed cylindrical steel shells’. Computational Mechanics, 37(6), pp. 530-536. https://doi.org/10.1007/s00466-005-0728-8
  14. Guggenberger, W. (1995) ‘Buckling and postbuckling of imperfect cylindrical shells under external pressure’, Thin Walled Structures, 23, pp. 351–366.
  15. Holst, F. G., Rotter, J. M., Calladine, C. R. (1994) ‘Imperfections in cylindrical shells resulting from fabrication misfits’, Journal of Engineering Mechanics, 125(4), pp. 410–418.
  16. Kiss, L. P., Gönczi, D., Baksa, A., Kovács, P. Z., Lukács, Zs. (2020) ’Experimental and numerical investigations on the stability of cylindrical shells’, Journal of Engineering Studies and Research, 26(4), pp. 34-39.
  17. Kiss, L. P. (2020) ’The effect of various imperfections on the buckling of aluminium shells’, Acta Technica Corviniensis – Bulletin of Engineering, 13(1), pp. 49- 52.
Adatbázis logók