Best practices for reducing the potential for progressive collapse in buildings

Ellingwood, Bruce R.; Smilowitz, Robert; Dusenberry, Donald O.; Duthinh, Dat; Lew, Hai S.; Carino, Nicholas J.

doi:10.6028/nist.ir.7396

Cited by 161 publications

(129 citation statements)

References 42 publications

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“…The dependency on the strain rate of the bolts' material is accounted considering literature reports: impact tests on A 325 bolts recovered from the WTC debris showed very low sensitivity to strain rate [9], showing that high strength steels are less sensible to the effects of strain rate variation. According to Chang and his co-authors [10], a dynamic increase factor (DIF) of 1.1 may be considered for the bolts.…”

Section: Strain Rate Evaluationmentioning

confidence: 99%

Material modelling of tensile steel component under impulsive loading

Ribeiro

Santiago

Rigueiro

2016

International Journal of Structural Integrity

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The "T-stub" model is used in Eurocode 3 -part 1.8 as part of the "component method" for the representation of steel connection's tension zone and is usually responsible for providing ductility to the connection. Looking forward to establish the "T-stub's" maximum displacement capacity, fracture simulation of steel elements is here explored following "element deletion" technique for a given level of ductile damage. Material softening and triaxial stress state dependency are assessed based on finite element analysis of common uniaxial tension tests. Numerical model describing the "T-stub" behaviour and displacement capacity are compared against experimental tests of statically loaded "T-stub" specimens with thicknesses of 10 and 15 mm. Based on the calibrated FE model for monotonic loading, the behaviour of this tensile component is evaluated for impulsive loading regimes. The material behaviour is improved to take into account the possible development of elevated strain rates based on results from Split-Hopkinson Bar tests, through the incorporation of the Johnson-Cook's elevated strain rate law for material strain-hardening description.

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Section: Strain Rate Evaluationmentioning

confidence: 99%

Material modelling of tensile steel component under impulsive loading

Ribeiro

Santiago

Rigueiro

2016

International Journal of Structural Integrity

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“…Ever since the collapse of the 110 storey twin towers in New York, USA, the research efforts have intensified on the topics such as progressive collapse of buildings [1,2], blast resistant design of buildings [3,4] and energy dissipation of structures [5,6]. Some studies exist on the topic of energy dissipation of structural members, however, they are generally confined to the automotive industry whose aim is to improve crash worthiness of their manufactured vehicles.…”

Section: Introductionmentioning

confidence: 99%

Reassessing the Plastic Hinge Model for Energy Dissipation of Axially Loaded Columns

Korol

Sivakumaran

2014

Journal of Structures

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This paper investigates the energy dissipation potential of axially loaded columns and evaluates the use of a plastic hinge model for analysis of hi-rise building column collapse under extreme loading conditions. The experimental program considered seven axially loaded H-shaped extruded aluminum structural section columns having slenderness ratios that would be typical of floor-to-ceiling heights in buildings. All seven test specimens initially experienced minor-axis overall buckling followed by formation of a plastic hinge at the mid-height region, leading to local buckling of the flanges on the compression side of the plastic hinge, and eventual folding of the compression flanges. The experimental energy absorption, based on load-displacement relations, was compared to the energy estimates based on section plastic moment resistance based on measured yield stress and based on measured hinge rotations. It was found that the theoretical plastic hinge model underestimates a column's actual ability to absorb energy by a factor in the range of 3 to 4 below that obtained from tests. It was also noted that the realizable hinge rotation is less than 180 ∘ . The above observations are based, of course, on actual columns being able to sustain high tensile strains at hinge locations without fracturing.

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“…Although disproportionate collapse has been an area of significant research lately (Ellingwood et al, 2007;Starossek, 2007;Structures Congress SEI, 2009), most efforts have focused on the effects of the phenomenon on buildings (Tomasetti et al, 2005;Byfield et al, 2007;Demonceau and Jaspart, 2008;Izzuddin et al, 2008;Gerasimidis et al, 2009;Kim and Kim, 2009;Knoll and Vogel, 2009;Dubina et al, 2010) rather than roofs or bridges. It is not surprising that most of the guidelines produced so far (GSA, 2003;DoD, 2009) include mainly criteria and requirements for building structures.…”

Section: Introductionmentioning

confidence: 99%

Disproportionate collapse analysis of cable-stayed steel roofs for cable loss

Gerasimidis

Baniotopoulos

2011

Int J Steel Struct

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Disproportionate collapse has been identified lately as a real cause of failure for structural engineering projects. Rare and unexpected, the phenomenon of disproportionate collapse usually results to many fatalities and thus, its analysis and mitigation is deemed necessary. This work describes the analysis of a cable-stayed steel roof under the scenario of a cable loss. The event of a cable loss is assumed to be brittle, while relevant recent recommendations suggest the application of a scaled equivalent static force at the points of the anchorage of the cable but in the opposite direction of the original cable force. In this paper, three different conditions have been considered in order to study the effect of the cable loss into the overall structural response of a typical cable-stayed roof; the level of the equivalent nodal load in the opposite direction of the original cable force varies. The steel structure of the roof, in its complexity, closer to responding as a cable-stayed bridge rather than a steel roof provides a useful template for conclusions; several topics regarding disproportionate collapse and cable losses are discussed.

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Best practices for reducing the potential for progressive collapse in buildings

Cited by 161 publications

References 42 publications

Material modelling of tensile steel component under impulsive loading

Material modelling of tensile steel component under impulsive loading

Reassessing the Plastic Hinge Model for Energy Dissipation of Axially Loaded Columns

Disproportionate collapse analysis of cable-stayed steel roofs for cable loss

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