Member and structural fragility of reinforced concrete structure under fire

Chaudhary, Ranjit Kumar; Roy, Tathagata; Matsagar, Vasant

doi:10.1108/jsfe-02-2019-0015

Cited by 14 publications

(1 citation statement)

References 31 publications

(37 reference statements)

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“…The procedure continues on the premise that the standards have been met (progressive spalling); the concrete structure could also instantaneously disintegrate with a massive energy release [2,6]. In general, fire may significantly impact structural behavior because of the degradation of material characteristics at elevated temperatures and the provision of indirect effects generated by restricted thermal expansion [7]. In fact, concrete structures often exhibit adequate fire resistance and satisfactory behavior in elevated temperature situations due to their low thermal expansion.…”

Section: Fig 1: Deformation Behavior Of Shcc Frc and Plain Concrete U...mentioning

confidence: 99%

Fire spalling behavior of high-strength concrete: A critical review

Amran

Huang

Onaizi

et al. 2022

Construction and Building Materials

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Section: Fig 1: Deformation Behavior Of Shcc Frc and Plain Concrete U...mentioning

confidence: 99%

Fire spalling behavior of high-strength concrete: A critical review

Amran

Huang

Onaizi

et al. 2022

Construction and Building Materials

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A Systematic Review on Different Approaches Used in the Development of Fragility Curves for Buildings

Rajapaksha¹,

Siriwardana²

2022

Lecture Notes in Civil Engineering

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Probabilistic Performance-based Fire Design of Structures: A Hazard-Centred and Consequence-Oriented Perspective

Franchini,

Galasso,

Torero

2024

Fire Technol

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Risk-based design and assessment methods are gaining popularity in performance-based structural fire engineering. These methods usually start by defining a set of hazard scenarios to use as analysis inputs. This approach, proven highly effective for other hazard types such as earthquakes, may not be optimal for fire safety design. Indeed, the strong coupling between the fire phenomenon and structural features enables an ad-hoc design variable selection (and/or optimisation) to reduce fire intensity, making fire scenarios additional design outputs. In addition, such a coupling effect implies that fire scenarios maximising consequences are structure specific. Building on these considerations, this paper discusses the limitations that arise at different analysis steps (i.e., fire-scenario and intensity treatment, identifying fire intensity measures, probabilistic fire hazard analysis, developing fire fragility models, and risk calculation) when using conventional risk-based approaches for design purposes. Furthermore, it compares such approaches with a fire safety design methodology (the Consequence-oriented Fire intensity Optimisation, CFO, approach) that addresses the identified limitations. The potential benefits of integrating the two approaches are also discussed. Finally, the fire design of a simplified steel-girder bridge is introduced as an illustrative example, comparing the consequence metrics and design updating strategies resulting from the two approaches.

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Member and structural fragility of reinforced concrete structure under fire

Cited by 14 publications

References 31 publications

Fire spalling behavior of high-strength concrete: A critical review

Fire spalling behavior of high-strength concrete: A critical review

A Systematic Review on Different Approaches Used in the Development of Fragility Curves for Buildings

Probabilistic Performance-based Fire Design of Structures: A Hazard-Centred and Consequence-Oriented Perspective

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