Abstract
This study proposes a blast load model that generates multiple impulse curves with appropriate shapes depending on the scaled distance and, thus, precisely calculates the blast load distribution over the structure surface. The suitability of the proposed model is examined by using the finite element simulation of a blast test with steel plates and comparing the predicted deflections with the measurements. The results reveal that the proposed model accurately calculates the blast load distribution over the structure surface. The predicted deflection profiles of the steel plates are closer to the measured deflection profiles when the proposed model is employed, as compared to the existing models, which produce only a single impulse curve.
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References
“Structures to Resist the Effects of Accidental Explosions,” Technical Manual 5–1300 (U. S. Department of the Army, 1990).
T. Børvik, A. G. Hanssen, M. Langseth, and L. Olovsson, “Response of Structures to Planar Blast Loads—A Finite Element Engineering Approach,” Comput. Struct. 87, 507–520 (2009).
SIMULIA. Abaqus Analysis User’s Manual, Vol. 1 (2012).
G. Randers-Pehrson and K. A. Bannister, Airblast Loading Model for DYNA2d and DYNA3d (Army Research Laboratory, 1997).
LS-DYNA Keyword User’s Manual, Version 971 (Livermore Software Technol. Corp., 2007).
Autodyn User’s Manual (ANSYS Inc.,2013).
V. H. Balden and G. N. Nurick, “Numerical Simulation of the Post-Failure Motion of Steel Plates Subjected to Blast Loading,” Int. J. Impact Eng. 32 (1), 14–34 (2005).
G. S. Langdon and G. K. Schleyer, “Deformation and Failure of Profiled Stainless Steel Blast Wall Panels. Pt. III: Finite Element Simulations and Overall Summary,” Int. J. Impact Eng. 32 (6), 988–1012 (2006).
L. Mazurkiewicz, J. Malachowski, P. Baranowski, and K. Damaziak, “Comparison of Numerical Testing Methods in Terms of Impulse Loading Applied to Structural Elements,” Theor. Appl. Mech. 51 (3), 615–625 (2013).
K. Sprangher, I. Vasilakos, D. Lecompte, H. Sol, and J. Vantomme, “Numerical Simulation and Experimental Validation of the Dynamic Response of Aluminum Plates under Free Air Explosions,” Int. J. Impact Eng. 54 (1), 83–95 (2003).
B. Zakrisson, B. Wikman, and H. Häggblad, “Numerical Simulations of Blast Loads and Structural Deformation from Near-Field Explosions in Air,” Int. J. Impact Eng. 38 (7), 597–612 (2011).
T. A. Hustad and A. L. Lindland, Aluminum Structures Exposed to Blast Loading (Norwegian Univ. Sci. Tech., 2014).
K. P. Dharmasena, H. N. G. Wadley, Z. Xue, and J. W. Hutchinson, “Mechanical Response of Metallic Honeycomb Sandwich Panel Structures to High Intensity Dynamic Loading,” Int. J. Impact Eng. 35, 1063–1074 (2008).
C. N. Kingery and G. Bulmash, Airblast Parameters from TNT Spherical air Burst and Hemispherical Surface Burst (U. S. Army Ballistic Research Laboratory, Aberdeen Proving Ground, 1984).
F. G. Friedlander, “The Diffraction of Sound Pulses. I. Diffraction by a Semi-Infinite Plane,” Proc. Roy. Soc. London, A 186, 322–344 (1946).
Fundamentals of Protective Design for Conventional Eeapons, Technical Manual (U. S. Department of the Army, 1986).
S. C. Yuen and G. N. Nurick, “Experimental and Numerical Studies on the Response of Quadrangular Stiffened Plates. Pt I: Subjected to Uniform Blast Load,” Int. J. Impact Eng. 31 (1), 55–83 (2005).
G. R. Johnson and W. H. Cook, “A Constitutive Model and Data for Metals Subjected to Large Strain, High Strain Rates and High Temperatures,” in Proc. 7th Int. Symp. on Ballistics, (1983), Vol. 54, pp. 541–547.
K. Nahshon et al., “Dynamic Shear Rupture of Steel Plates,” J. Mech. Mat. Struct. 2 (10), 2049–2066 (2007).
S. E. Rigby and P. W. Sielicki, “An Investigation of TNT Equivalence of Hemispherical PE4 Charges,” Eng. Trans. 62, 423–35 (2014).
G. Cowper and P. S Symonds, Strain-Hardening and Strain-Rate Effects in the Impact Loading of Cantilever Beams (Brown Univ., U.S.A., 1957).
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Original Russian Text © B.S. Jang, S.H. Lee, Y. Lee.
Published in Fizika Goreniya i Vzryva, Vol. 54, No. 6, pp. 121–130, November–December, 2018.
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Jang, B.S., Lee, S.H. & Lee, Y. Blast Load Model Generating Multiple Impulse Curves for Different Scaled Distances. Combust Explos Shock Waves 54, 737–746 (2018). https://doi.org/10.1134/S001050821806014X
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DOI: https://doi.org/10.1134/S001050821806014X