Structural Analysis of Compression Deformation and Failure of Aluminum in Fire
Publication: Journal of Structural Engineering
Volume 137, Issue 7
Abstract
This paper presents a finite-element (FE) modeling approach to predict the deformation, softening, and failure of compression-loaded aluminum structures exposed to fire. A fully coupled thermal-mechanical FE model is outlined. The FE model can analyze the thermal profile and deformation as well as the initial and final plastic collapse of aluminum structures in fire. It calculates the temperature profile of an aluminum structure exposed to unsteady-state heating conditions representative of fire. Using the temperature profile, the elastic and plastic deformations together with the loss in the compression load capacity of an aluminum structure caused by elastic softening, time-independent plastic (yield) softening, and time-dependent plastic (creep) softening effects are analyzed by using a mechanics-based FE solution. The modeling approach is validated by structural tests on an aluminum alloy (5083 Al) plate supporting an applied compression load while locally heated at different radiant heat flux (temperature) levels. The modeling approach can estimate the deformations, initiation of plastic collapse, and final failure of the aluminum test article for heat flux levels representative of different fire types. The FE model described in this paper can be used as the basis for performing complex deformation and failure analysis of compression-loaded aluminum (and other metallic) structures in fire.
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Acknowledgments
This research was performed as part of a research project (P2.1.3) within the Cooperative Research Centre for Advanced Composite Structures (CRC-ACS Ltd). The study was funded by the U.S. Office of Naval Research (Grant No. UNSPECIFIEDN00014-07010514) under the direction of Dr. L. Couchman. The authors thank Peter Tkatchyk of Royal Melbourne Institute of Technology (RMIT) for constructing the fire-under-load test apparatus and for technical assistance in the experimental testing.
References
Faggiano, B., De Matteis, G., Landolfo, R., and Mazzolani, F. M. (2004). “Behaviour of aluminium alloy structures under fire.” J. Civil Eng. Manage., 10(3), 183–190.
Hopperstad, O. S., Langseth, M., and Hanssen, L. (1997). “Ultimate compressive strength of plate elements in aluminium: Correlation of finite element analyses and tests.” Thin-Walled Struct., 29(1–4), 31–46.
Kandare, E., Feih, S., Lattimer, B. Y., and Mouritz, A. P. (2010a). “Larson-Miller failure modelling of aluminium in fire.” Metall. Mater. Trans. A, 41(1), 3091–3099.
Kandare, E., Feih, S., Kotsookos, A., Mathys, Z., Lattimer, B. Y., and Mouritz, A. P. (2010b). “Creep-based life prediction modelling of aluminium in fire.” Mater. Sci. Eng. A, 527(4–5), 1185–1193.
Kaufmann, J. G. (1999). Properties of aluminium alloys—Tensile, creep and fatigue data at high and low temperatures, ASM International, Materials Park, OH.
Khanna, S. K., Long, X., Porter, W. D., Liu, H. W. K. C., Radovic, M., and Lara-Curzio, E. (2005). “Residual stresses in spot-welded new generation aluminium alloys. Part A: Thermophysical and thermomechanical properties of 6111 and 5754 aluminium alloys.” Sci. Technol. Weld. Joining, 10(1), 82–87.
Langhelle, N. K., and Amdahl, J. (2001). “Experimental and numerical analysis of aluminium columns subjected to fire.” Proc., 11th Int. Offshore and Polar Engineering Conference, Vol. IV, Stavanger, Norway.
Langhelle, N. K., Eberg, E., Amdahl, J., and Lundberg, S. (1996). “Buckling tests of aluminium columns at elevated temperatures.” Proc., 15th Int. Conf. Offshore Mechanics and Arctic Engineering (OMAE), Vol. II, Safety and Reliability, ASME, Florence, Italy.
Larson, F. R., and Miller, J. (1952). “A time-temperature relationship for rupture and creep stresses.” Trans. ASME, 74(5), 765–775.
Lundberg, S. (1994). Material aspect of fire design, TALAT Lectures 2502, European Aluminium Association.
Maljaars, J., Soetens, F., and Katgerman, L. (2008). “Constitutive model for aluminum alloys exposed to fire conditions.” Metall. Mater. Trans. A, 39A(4), 778–789.
Maljaars, J., Soetens, F., and Snijder, H. H. (2009b). “Local buckling of aluminium structures exposed to fire. Part 2: Finite element models.” Thin-Walled Struct., 47(11), 1418–1428.
Maljaars, J., Twilt, L., and Soetens, F. (2009a). “Flexural buckling of fire exposed aluminium columns.” Fire Saf. J., 44(5), 711–717.
Suzuki, J., Ohmiya, Y., Wakamatsu, T., Harada, K., Yuasa, S., and Kohno, M. (2005). “Evaluation of fire resistance of aluminum alloy members.” Fire Sci. Technol., 24(4), 237–255.
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© 2011 American Society of Civil Engineers.
History
Received: Mar 10, 2010
Accepted: Sep 12, 2010
Published online: Sep 22, 2010
Published in print: Jul 1, 2011
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