Calibrated Numerical Approach for the Dynamic Analysis of Glass Curtain Walls under Spheroconical Bag Impact

The structural design of glass curtain walls and facades is a challenging issue, considering that building envelopes can be subjected extreme design loads. Among others, the soft body impact (SBI) test protocol represents a key design step to protect the occupants. While in Europe the standardized protocol based on the pneumatic twin-tire (TT) impactor can be nowadays supported by Finite Element (FE) numerical simulations, cost-time consuming experimental procedures with the spheroconical bag (SB) impactor are still required for facade producers and manufacturers by several technical committees, for the impact assessment of novel systems. At the same time, validated numerical calibrations for SB are still missing in support of designers and manufacturers. In this paper, an enhanced numerical approach is proposed for curtain walls under SB, based on a coupled methodology inclusive of a computationally efficient two Degree of Freedom (2-DOF) and a more geometrically accurate Finite Element (FE) model. As shown, the SB impactor is characterized by stiffness and dissipation properties that hardly match with ideal rigid elastic assumptions, nor with the TT features. Based on a reliable set of experimental investigations and records, the proposed methodology acts on the time history of the imposed load, which is implicitly calibrated to account for the SB impactor features, once the facade features (flexibility and damping parameters) are known. The resulting calibration of the 2-DOF modelling parameters for the derivation of time histories of impact force is achieved with the support of experimental measurements and FE model of the examined facade. The potential and accuracy of the method is emphasized by the collected experimental and numerical comparisons. Successively, the same numerical approach is used to derive a series of iso-damage curves that could support practical design calculations.

[1]  Claudio Amadio,et al.  Viscoelastic spider connectors for the mitigation of cable-supported façades subjected to air blast loading , 2012 .

[2]  Chiara Bedon,et al.  Mechanical analysis and characterization of IGUs with different silicone seaed spacer connections: part 2—modelling , 2020 .

[3]  Chiara Bedon,et al.  Design of blast-loaded glazing windows and facades: a review of essential requirements towards standardization , 2016 .

[4]  Jens Schneider,et al.  Zwei Verfahren zum rechnerischen Nachweis der dynamischen Beanspruchung von Verglasungen durch weichen Stoß , 2011 .

[5]  Chiara Bedon,et al.  Low velocity impact performance investigation on square hollow glass columns via full-scale experiments and Finite Element analyses , 2017 .

[6]  J. Dear,et al.  Deformation and damage mechanisms of laminated glass windows subjected to high velocity soft impact , 2017 .

[7]  Tomonori Yamada,et al.  Numerical analysis of impact failure of automotive laminated glass: A review , 2017 .

[8]  Luigi Biolzi,et al.  Laminated Glass Cantilevered Plates under Static and Impact Loading , 2018, Advances in Civil Engineering.

[9]  Stephen M. Morse,et al.  Comparison of methods to determine load sharing of insulating glass units for environmental loads , 2016 .

[10]  Claudio Amadio,et al.  Elastoplastic dissipative devices for the mitigation of blast resisting cable-supported glazing façades , 2012 .

[11]  Chiara Bedon,et al.  Mechanical analysis and characterization of IGUs with different spacers—part 1: experiments , 2020 .

[12]  David Lange,et al.  Performance of structural glass facades under extreme loads – Design methods, existing research, current issues and trends , 2018 .

[13]  Marcin Kozłowski,et al.  Experimental and numerical assessment of structural behaviour of glass balustrade subjected to soft body impact , 2019, Composite Structures.

[14]  Lutz Karl Heinz Hermanns,et al.  Viscoelastic vibration damping identification methods. Application to laminated glass , 2011 .

[15]  Jens Schneider,et al.  Simulating soft body impact on glass structures , 2016 .

[16]  Daniel Papán,et al.  Experimental mechanical analysis of traditional in-service glass windows subjected to dynamic tests and hard body impact , 2021 .

[17]  Claudio Amadio,et al.  Vibration Analysis and Dynamic Characterization of Structural Glass Elements with Different Restraints Based on Operational Modal Analysis , 2019, Buildings.

[18]  Nelson Lam,et al.  Drift Performance of Point Fixed Glass Façade Systems , 2014 .

[19]  Chris J. Newman Evaluation of an impact standard for curtain walling , 2004 .

[20]  Jan Belis,et al.  Sustainable facade design for glazed buildings in a blast resilient urban environment , 2018 .