A glazing fa?ade subjected to blast loads has a structural behaviour that strongly differs from the typical response of a glazing system subjected to ordinary loads. Consequently, sophisticated modelling techniques are required to identify correctly its criticalities. The paper investigates the behaviour of a cable-supported fa?ade subjected to high-level blast loading. Nonlinear dynamic analyses are performed in ABAQUS/Explicit using a sophisticated FE-model (M01), calibrated to dynamic experimental and numerical results. The structural effects of the total design blast impulse, as well as only its positive phase, are analyzed. At the same time, the possible cracking of glass panels is taken into account, since this phenomenon could modify the response of the entire fa?ade. Finally, deep investigations are dedicated to the bearing cables, since subjecting them to elevated axial forces and their collapse could compromise the integrity of the cladding wall. Based on results of previous studies, frictional devices differently applied at their ends are presented to improve the response of the fa?ade under the impact of a high-level explosion. Structural effects of various solutions are highlighted through dynamic simulations. Single vertical devices, if appropriately calibrated, allow reducing significantly the axial forces in cables, and lightly the tensile stresses in glass panes. 1. Introduction Modern buildings are frequently clad with futuristic glazing fa?ades. In them, glass panels have not only architectural and aesthetic functions, but constitute structural components able to interact with the supporting metallic systems (frames, connectors, pretensioned cables). Recently, numerous authors studied the dynamic response of different glass-cladding typologies, giving particular attention to the effects of initial imperfections [1], wind loads [2], or seismic events [3]. In the last years, also the blast-resistance of glass curtain walls received a remarkable increase of interest. Norville and Conrath [4] proposed simplified procedures for the design of blast resistant glazing elements. Larcher et al. [5] numerically simulated the behaviour of laminated glass loaded by air blast waves, by taking into account also the cracking of glass panes. Weggel and Zapata [6] numerically investigated the dynamic behaviour of a nearly conventional laminated glass curtain wall with split screw spline mullions subjected to low-level blast loading. Generally, the principal objective in the design of blast-resistant glazing systems consists in avoiding injuries and
References
[1]
S. L. Chan, Y. Liu, and A. Lee, “Nonlinear analysis of pre-tensioned glass wall facade by stability function with initial imperfection,” Frontiers of Architecture and Civil Engineering in China, vol. 4, no. 3, pp. 376–382, 2010.
[2]
Q. S. Li and G. Q. Li, “Time-dependent reliability analysis of glass cladding under wind action,” Engineering Structures, vol. 27, no. 11, pp. 1599–1612, 2005.
[3]
R. Q. Feng, L. L. Zhang, Y. Wu, and S. Z. Shen, “Dynamic performance of cable net facades,” Journal of Constructional Steel Research, vol. 65, no. 12, pp. 2217–2227, 2009.
[4]
H. S. Norville and E. J. Conrath, “Simplified Design Procedure for Blast Resistant Glazing,” Glass Processing Days, 2001.
[5]
M. Larcher, G. Solomos, F. Casadei, and N. Gebbeken, “Experimental and numerical investigations of laminated glass subjected to blast loading,” International Journal of Impact Engineering, vol. 39, no. 1, pp. 42–50, 2012.
[6]
D. C. Weggel and B. J. Zapata, “Laminated glass curtain walls and laminated glass lites subjected to low-level blast loading,” Journal of Structural Engineering, vol. 134, no. 3, pp. 466–477, 2008.
[7]
C. Amadio and C. Bedon, “Elastoplastic dissipative devices for the mitigation of blast resisting cable-supported glazing fa?ades,” Engineering Structures, vol. 39, pp. 103–115, 2012.
[8]
C. Amadio and C. Bedon, “Viscoelastic spider connectors for the mitigation of cable-supported fa?ades subjected to air blast loading,” Engineering Structures, vol. 42, pp. 190–200, 2012.
[9]
F. Wellershoff, “Design methods and structural components of blast enhanced fa?ades,” in Proceedings of the Challenging Glass 3-International Conference on Architectural and Structural Applications of Glass, F. Bos, C. Louter, R. Nijsse, and F. Veer, Eds., pp. 28–29, IOS Press, TU Delft, The Netherlands, June 2012.
[10]
GSA-TSO1-2003, “Test Method for Glazing and Window Systems Subject to Dynamic Overpressure Loadings,” U.S. General Service Administration.
[11]
P. S. Bulson, Explosive Loading of Engineering Structures, E & FN Spon, Chapman & Hall, London, UK, 1997.
[12]
TM 5-1300, The Design of Structures to Resist the Effects of Accidental Explosions, U.S. Department of the Army, The Navy and the Air Force, Technical Manual, Washington, DC, USA, 1990.
[13]
ABAQUS ver. 6.5 User Manual, Hibbitt, Karlsson and Sorensen, Pawtucket, RI, USA, 2005.
[14]
E. Sommer, “Formation of fracture “lances” in glass,” Engineering Fracture Mechanics, vol. 1, no. 3, pp. 539–546, 1969.
[15]
C. Amadio and C. Bedon, “Blast analysis of laminated glass curtain walls equipped by viscoelastic dissipative devices,” Buildings, vol. 2, no. 3, pp. 359–383, 2012.
[16]
J. Wei and L. R. Dharani, “Response of laminated architectural glazing subjected to blast loading,” International Journal of Impact Engineering, vol. 32, no. 12, pp. 2032–2047, 2006.
[17]
J. H. Park, B. W. Moon, K. W. Min, S. K. Lee, and C. Kyeong Kim, “Cyclic loading test of friction-type reinforcing members upgrading wind-resistant performance of transmission towers,” Engineering Structures, vol. 29, no. 11, pp. 3185–3196, 2007.
