Experimental and Numerical Simulation Investigation on Crushing Response of Foam-Filled Conical Tubes Stiffened with Annular Rings
الموضوعات :
1 - Department of Mechanical Engineering, Semnan Branch, Islamic Azad University, Semnan, Iran
الکلمات المفتاحية: Polyurethane Foam, energy absorption, Maximum crushing load, Conical, Annular rings, CFE,
ملخص المقالة :
In this paper, crashworthiness characteristics of conical steel tubes stiffened by annular rings and rigid polyurethane foam are investigated. For this purpose, wide circumferential rings are created from the outer surface of the conical tube at some determined areas along tube length. In fact, this method divides a long conical tube into several tubes of shorter length. When this structure is subjected to axial compression, folds are shaped within the space of these annular rings. In this study, several numerical simulations using ABAQUS 5.6 finite element explicit code are carried out to study of crashworthiness characteristics of the empty and the foam-filled thin-walled conical tubes. In order to verify these numerical results, a series of quasi-static axial compression tests are performed. Moreover, load-displacement curves, deformation mechanism of the structure, energy absorption, crush force efficiency (CFE), initial peak load with different number of rings are described under axial compression. The results show that a conical tube with stiff rings as a shock absorber could be improved or adjusted the crushing mode of deformation and energy absorption ability.
[1] Abramowicz W., 2003, Thin-walled structures as impact energy absorbers, Thin-Walled Structures 41: 91-107.
[2] Nagel G., Thambiratnam D., 2004, A numerical study on the impact response and energy absorption of tapered thin-walled tubes, International Journal of Mechanical Sciences 46: 201-216.
[3] Nagel G., Thambiratnam D., 2005, Computer simulation and energy absorption of tapered thin-walled rectangular tubes, Thin-Walled Structures 43: 1225-1242.
[4] Aljawi A., Alghamdi A., Abu-Mansour T., Akyurt M., 2005, Inward inversion of capped-end frusta as impact energy absorbers, Thin-Walled Structures 43: 647-664.
[5] Guillow S., Lu G., Grzebieta R., 2001, Quasi-static axial compression of thin-walled circular aluminium tubes, International Journal of Mechanical Sciences 43: 2103-2123.
[6] Alavi Nia A., Haddad Hamedani J., 2010, Comparative analysis of energy absorption and deformations of thin walled tubes with various section geometries, Thin-Walled Structures 48: 946-954.
[7] Mokhtarnezhad F., Salehghaffari S., Tajdari M., 2009, Improving the crashworthiness characteristics of cylindrical tubes subjected to axial compression by cutting wide grooves from their outer surface, International Journal of Crashworthiness 14: 601-611.
[8] Salehghaffari S., Tajdari M., Panahi M., Mokhtarnezhad F., 2010, Attempts to improve energy absorption characteristics of circular metal tubes subjected to axial loading, Thin-Walled Structures 48: 379-390.
[9] Reid S., Reddy T., 1986, Static and dynamic crushing of tapered sheet metal tubes of rectangular cross-section, International Journal of Mechanical Sciences 28: 623-637.
[10] Mamalis A., Johnson W., 1983, The quasi-static crumpling of thin-walled circular cylinders and frusta under axial compression, International Journal of Mechanical Sciences 25:713-732.
[11] Mamalis A., Johnson W., Viegelahn G., 1984, The crumpling of steel thin-walled tubes and frusta under axial compression at elevated strain-rates: some experimental results, International Journal of Mechanical Sciences 26: 537-547.
[12] Mamalis A., Manolakos D., Saigal S., Viegelahn G., Johnson W., 1986, Extensible plastic collapse of thin-wall frusta as energy absorbers, International Journal of Mechanical Sciences 28: 219-229.
[13] Gupta N., Sheriff N.M., Velmurugan R., 2006, A study on buckling of thin conical frusta under axial loads, Thin-Walled Structures 44: 986-996.
[14] Sheriff N.M., Gupta N., Velmurugan R., Shanmugapriyan N., 2008, Optimization of thin conical frusta for impact energy absorption, Thin-Walled Structures 46: 653-666.
[15] Spagnoli A., Chryssanthopoulos M., 1999, Elastic buckling and postbuckling behaviour of widely-stiffened conical shells under axial compression, Engineering structures 21: 845-855.
[16] Gupta N., Prasad G.E., Gupta S., 1997, Plastic collapse of metallic conical frusta of large semi-apical angles, International Journal of Crashworthiness 2: 349-366.
[17] El-Sobky H., Singace A., Petsios M., 2001, Mode of collapse and energy absorption characteristics of constrained frusta under axial impact loading, International Journal of Mechanical Sciences 43: 743-757.
[18] Prasad G.E., Gupta N., 2005, An experimental study of deformation modes of domes and large-angled frusta at different rates of compression, International Journal of Impact Engineering 32: 400-415.
[19] Ghamarian A., Zarei H., 2012, Crashworthiness investigation of conical and cylindrical end-capped tubes under quasi-static crash loading, International Journal of Crashworthiness 17: 19-28.
[20] Rezvani M.J., Nouri M.D., 2013, Axial crumpling of aluminum frusta tubes with induced axisymmetric folding patterns, Arabian Journal for Science and Engineering 39: 2179-2190.
[21] Damghani Nouri M., Rezvani M.J., 2012, Experimental investigation of polymeric foam and grooves effects on crashworthiness characteristics of Thin-walled conical tubes, Experimental Techniques 38: 54-63.
[22] Rezvani M., Damghani Nouri M., 2015, Analytical Model for Energy Absorption and Plastic Collapse of Thin-Walled Grooved Frusta Tubes, Mechanics of Advanced Materials and Structures 22: 338-348.
[23] Seitzberger M., Rammerstorfer F.G., Gradinger R., Degischer H., Blaimschein M., Walch C., 2000, Experimental studies on the quasi-static axial crushing of steel columns filled with aluminium foam, International Journal of Solids and Structures 37: 4125-4147.
[24] Ahmad Z., Thambiratnam D.P., 2009, Dynamic computer simulation and energy absorption of foam-filled conical tubes under axial impact loading, Computers & Structures 87: 186-197.
[25] Abramowicz W., Wierzbicki T., 1988, Axial crushing of foam-filled columns, International Journal of Mechanical Sciences 30: 263-271.
[26] Yamada Y., Banno T., Xie Z., Wen C., 2005, Energy absorption and crushing behaviour of foam-filled aluminium tubes, Materials transactions 46: 2633-2636.
[27] Reddy T., Wall R., 1988, Axial compression of foam-filled thin-walled circular tubes, International Journal of Impact Engineering 7:151-166.
[28] Thornton P.,1980, Energy absorption by foam filled structures, SAE International 800081.
[29] Reid S., Reddy T., Gray M., 1986, Static and dynamic axial crushing of foam-filled sheet metal tubes, International Journal of Mechanical Sciences 28: 295-322.
[30] Darvizeh A., Darvizeh M., Ansari R., Meshkinzar A., 2013, Effect of low density, low strength polyurethane foam on the energy absorption characteristics of circumferentially grooved thick-walled circular tubes, Thin-Walled Structures 71: 81-90.
[31] Ahmad Z., Thambiratnam D., 2009, Crushing response of foam-filled conical tubes under quasi-static axial loading, Materials & Design 30: 2393-2403.
[32] Adachi T., Tomiyama A., Araki W., Yamaji A., 2008, Energy absorption of a thin-walled cylinder with ribs subjected to axial impact, International Journal of Impact Engineering 35: 65-79.
[33] Salehghaffari S., Rais-Rohani M., Najafi A., 2011, Analysis and optimization of externally stiffened crush tubes, Thin-Walled Structures 49: 397-408.
[34] Rezvani M.J., Jahan A., 2015, Effect of initiator, design, and material on crashworthiness performance of thin-walled cylindrical tubes: A primary multi-criteria analysis in lightweight design, Thin-Walled Structures 96:169-182.
[35] Ghamarian A., Abadi M.T., 2011, Axial crushing analysis of end-capped circular tubes, Thin-Walled Structures 49: 743-752.
[36] Mirfendereski L., Salimi M., Ziaei-Rad S., 2008, Parametric study and numerical analysis of empty and foam-filled thin-walled tubes under static and dynamic loadings, International Journal of Mechanical Sciences 50: 1042-1057.