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Fire Technology
Erschienen in: Fire Technology 4/2019

06.08.2018

Fire Fragility Functions for Steel Frame Buildings: Sensitivity Analysis and Reliability Framework

verfasst von: Thomas Gernay, Negar Elhami Khorasani, Maria Garlock

Erschienen in: Fire Technology | Ausgabe 4/2019

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Abstract

Fire fragility functions are a powerful method to characterize the probabilistic vulnerability of buildings to fire in the context of urban resilience assessment. But this method is recent and the influence of the different uncertain parameters on the functions has not been systematically studied. The first objective of this paper is to identify the prevailing parameters in constructing fire fragility functions for steel frame buildings. To this end, sensitivity analyses are conducted using Monte Carlo Simulations and a variance-based method, focusing on column failure fragilities. Fragilities for buildings with 3 to 12 stories, 0 to 3 h fire resistance rating and various occupancies are compared, assuming compartment areas ranging from 15 m2 to 80 m2. Results show that uncertainties in fire, heat transfer and structural models all generate significant variability in the fire fragility. In addition to fire load as the intensity measure, significant probabilistic parameters are the compartment geometry and openings, the thickness and thermal conductivity of fire protection, and the temperature dependent mechanical properties of steel. The second objective is to clarify the incorporation of fragility functions in a comprehensive structural fire reliability framework. A methodology for combining the functions with the ignition likelihood per year and with the fire loading in MJ/m2 is described, yielding annual probability estimates of column failure due to fire in the buildings. For a sprinklered office building designed according to prescriptive provisions, this annual probability ranges from 1.90 × 10−7 to 0.12 × 10−7 per year as a function of the building height. The probabilistic modeling techniques proposed in this paper can be used to establish consistent reliability levels in different buildings and to evaluate resilience for fire scenarios.
Vorheriger Artikel Severity Measures and Stripe Analysis for Probabilistic Structural Fire Engineering
Nächster Artikel Development of an Integrated Risk Assessment Method to Quantify the Life Safety Risk in Buildings in Case of Fire

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Literatur
1.
Elhami Khorasani N, Garlock M, Gardoni P (2014) Fire load: survey data, recent standards, and probabilistic models for office buildings. Eng Struct 58: 152–165CrossRef
2.
Bruls A, Cajot LG, Franssen JM (1988) Characterization of an insulating material with regard to ECCS recommendations for the fire safety of steel structures. J Constr Steel Res 9(2): 111–135CrossRef
3.
Bentz DP, Prasad KR (2007) Thermal performance of fire resistive materials I. Characterization with respect to thermal performance models. Report No. NISTIR 7401, NIST, Gaithersburg, MD
4.
Luecke WE, Banovic S, McColskey JD (2011) High temperature tensile constitutive data and models for structural steels in fire. NIST Technical Note 1714, Gaithersburg, MD
5.
Naus D (2010) A compilation of elevated temperature concrete material property data and information for use in assessments of nuclear power plant reinforced concrete structures. US Nuclear Regulatory Commission, Office of Nuclear Regulatory Research, Washington, DC
6.
Hadjisophocleous GV, Benichou N (1999) Performance criteria used in fire safety design. Autom Constr 8: 489–501CrossRef
7.
Hopkin D, Van Coile R, Lange D (2017) Certain uncertainty—demonstrating safety in fire engineering and the need for safety targets. In: SFPE Europe, 07.
8.
Cimellaro GP, Reinhorn AM, Bruneau M (2010) Framework for analytical quantification of disaster resilience. Eng Struct 32(11): 3639–3649CrossRef
9.
Rota M, Penna A, Magenes G (2010) A methodology for deriving analytical fragility curves for masonry buildings based on stochastic nonlinear analyses. Eng Struct 32(5): 1312–1323CrossRef
10.
Phan HN, Paolacci F, Bursi OS, Tondini N (2017) Seismic fragility analysis of elevated steel storage tanks supported by reinforced concrete columns. J Loss Prev Process Ind 47: 57–65CrossRef
11.
Shinozuka M, Feng MG, Lee J, Naganuma T (2000) Statistical analysis of fragility curves. J Eng Mech ASCE 126(12): 1224–1231CrossRef
12.
Van Coile R, Caspeele R, Taerwe L (2014) Reliability-based evaluation of the inherent safety presumptions in common fire safety design. Eng Struct 77:181–192CrossRef
13.
De Sanctis G, Fischer K, Kohler J, Faber MH, Fontana M (2014) Combining engineering and data-driven approaches: development of a generic fire risk model facilitating calibration. Fire Saf J 70: 23–33CrossRef
14.
Anderson J, Lange D, Bostrom L (2016) Applying uncertainty quantification in modelling of a steel beam exposed to fire. In: 9th international conference on structures in fire (SiF 2016). Princeton University, NJ, USA, pp 925–932
15.
Molkens T, Van Coile R, Gernay T (2017) Assessment of damage and residual load bearing capacity of a concrete slab after fire: applied reliability-based methodology. Eng Struct 150: 969–985CrossRef
16.
Van Coile R, Balomenos GP, Pandey MD, Caspeele R (2017) An unbiased method for probabilistic fire safety engineering, requiring a limited number of model evaluations. Fire Technol 53(5): 1705–1744CrossRef
17.
18.
Guo Q, Jeffers AE (2015) Finite-element reliability analysis of structures subjected to fire. J Struct Eng 141(4): 04014129CrossRef
19.
Elhami Khorasani N, Gernay T, Garlock M (2016) Probabilistic measures of earthquake effects on fire performance of tall buildings. In: Proceedings of the sixth international conference on structural engineering, mechanics and computation. Taylor & Francis, Routledge, pp 1744–1749
20.
21.
Annerel E, Caspeele R, Taerwe L (2013) Full-probabilistic analysis of concrete beams during fire. J Struct Fire Eng 4(3):165–174CrossRef
22.
23.
Wang L, Van Coile R, Caspeele R, Taerwe L (2018) A parametric study on concrete columns exposed to biaxial bending at elevated temperatures using a probabilistic analysis. In: High tech concrete: where technology and engineering meet. Springer, Cham, pp 1662–1670
24.
25.
Shrivastava M, Abu AK, Dhakal RP, Moss PJ (2017) Efficiency of different intensity measures for probabilistic fire engineering. In: Hao H, Zhang C (eds) Proceedings of the 24th Australasian conference on mechanics of structures and materials: advancements and challenges. Taylor and Francis Group
26.
Lange D, Devaney S, Usmani A (2014) An application of the PEER performance based earthquake engineering framework to structures in fire. Eng Struct 66(0): 100–115CrossRef
27.
Gernay T, Elhami Khorasani N, Garlock M (2016) Fire fragility curves for steel buildings in a community context: a methodology. Eng Struct 113: 259–276CrossRef
28.
Elhami Khorasani N, Gernay T, Garlock M (2015) Tools for measuring a city’s resilience in a fire following earthquake scenario. In: IABSE conference on structural engineering: providing solutions to global challenges, Geneva, Switzerland, pp 886–889
29.
Elhami Khorasani N, Gernay T, Garlock M (2017) Data-driven probabilistic post-earthquake fire ignition model for a community. Fire Saf J 94: 33–44CrossRef
30.
Rush D, Lange D (2017) Towards a fragility assessment of a concrete column exposed to a real fire–tisova fire test. Eng Struct 150, 537–549CrossRef
31.
Marasco S, Zamani Noori A, Cimellaro GP (2017) Cascading hazard analysis of a hospital building. J Struct Eng 143(9): 04017100CrossRef
32.
Guo Q, Shi K, Jia Z, Jeffers AE (2013) Probabilistic evaluation of structural fire resistance. Fire Technol 49(3), 793–811CrossRef
33.
Franssen JM, Gernay T (2017) Modeling structures in fire with SAFIR®: theoretical background and capabilities. J Struct Fire Eng 8(3), 300–323CrossRef
34.
Hopkin D, Van Coile R, Fu I (2018) Developing fragility curves and estimating failure probabilities for protected steel structural elements subjected to fully developed fires. In: 10th international conference on structures in fire (SiF 2018). Belfast, UK.
35.
Saltelli A, Ratto M, Andres T, Campolongo F, Cariboni J, Saisana M, Tarantola S (2008) Global sensitivity analysis: the primer. Wiley, New YorkMATH
36.
FEMA (2014) Hazus: MH 2.1 technical manual—earthquake model. Developed by the Department of Homeland Security. Federal Emergency Management Agency. Mitigation Division. Washington, DC
37.
SAC (2000) FEMA 355C: state of the art report on system performance of steel moment frames subject to earthquake ground shaking, Federal Emergency Management Agency, Washington, D.C
38.
IBC (2012) International building code. International Code Council Inc., Country Club Hills
39.
Isolatek (2014) Isolatek international product manual. Isolatek International, Stanhope
40.
Drysdale D (1998) An introduction to fire dynamics, 2nd edn. Wiley, Chichester
41.
EC1 (2002) Eurocode 1: actions on structures—part 1–2: general actions—actions on structures exposed to fire. EN 1991-1-2. CEN, Brussels
42.
Reitgruber S, Di Blasi C, Franssen JM (2006) Some comments on the parametric fire model of Eurocode 1. In: Conference on fire in enclosures, University of Ulster, Jordanstown, UK, pp 1–14
43.
Hamilton SR (2011) Performance-based fire engineering for steel framed structure: a probabilistic methodology. Ph.D. Dissertation, Department of Civil and Environmental Engineering, Stanford University
44.
NFPA: National Fire Protection Association (2012) NFPA 557 standard for determination of fire loads for use in structural fire protection design. NFPA, Quincy
45.
JCSS (2001) JCSS probabilistic model code—part 2: load models, joint committee on structural safety. ISBN 978-3-909386-79-6.
46.
EC3 (2005) Eurocode 3: design of steel structures—part 1–2: general rules—structural fire design. EN 1993-1-2. CEN, Brussels.
47.
Carino NJ, Stranes MA, Gross JL, Yang JC et al (2005) Federal building and fire safety investigation of the world trade center disaster—passive fire protection, NIST NCSTAR 1-6A, September
48.
49.
Van Coile R, Gernay T, Elhami Khorasani N, Hopkin D (2018) Evaluating uncertainty in steel-composite structure under fire—application of the ME-MRDM. In: 10th international conference on structures in fire, FireSERT, Ulster University, Belfast, UK
50.
Ellingwood BR (2005) Load combination requirements for fire-resistant structural design. J Fire Prot Eng 15(1), 43–61.CrossRef
51.
Law A, Butterworth N, Stern-Gottfried J (2015) A risk based framework for time equivalence and fire resistance. Fire Technol 50(4): 771–784.CrossRef
52.
Vassart O, Zhao B, Cajot LG, Robert, F, Meyer U, Frangi A (2014) Eurocode: background and applications. Structural fire design. Worked examples. JRC, Luxemburg.
53.
Hopkin D, Anastasov S, Swinburne K, Rush D, Van Coile R (2017) Applicability of ambient temperature reliability targets for appraising structures exposed to fire. In: 2nd international conference on structural safety under fire and blast loading, London, UK, Sep 10–12.
Metadaten
Titel
Fire Fragility Functions for Steel Frame Buildings: Sensitivity Analysis and Reliability Framework
verfasst von
Thomas Gernay
Negar Elhami Khorasani
Maria Garlock
Publikationsdatum
06.08.2018
Verlag
Springer US
Erschienen in
Fire Technology / Ausgabe 4/2019
Print ISSN: 0015-2684
Elektronische ISSN: 1572-8099
DOI
https://doi.org/10.1007/s10694-018-0764-5

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