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Fire Technology

Erschienen in:

18.10.2021

OpenFIRE: An Open Computational Framework for Structural Response to Real Fires

verfasst von: Aatif Ali Khan, Mustesin Ali Khan, Chao Zhang, Liming Jiang, Asif Usmani

Erschienen in: Fire Technology | Ausgabe 2/2022

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Abstract

More than 1300 new buildings over 200 m tall have been built since the year 2000, representing 80% of the total number of supertall buildings globally. The proliferation of such challenging architecture in densely populated urban environments has led engineers to question the fitness of the prevalent prescriptive approaches in ensuring the safety of occupants in the event of a fire. This paper proposes a more rational methodology to estimate scientifically appropriate boundary conditions to represent realistic fire scenarios on the structure for more credible simulation of the consequent structural response using an integrated computational tool. An open-source framework, “OpenFIRE” is developed to implement the methodology. OpenFIRE is capable of simulating the whole sequence i.e., development of a fire scenario, heat transfer to the structure, and the thermomechanical response of the structure, through a sequential coupling of CFD tools with FE software. OpenFIRE exploits the capabilities of available tools such as FDS and OpenSEES and integrates them to produce a free, efficient, and open source computational framework which allows to customise and modify the source codes. It can bring structural fire community a step closer towards the adoption of performance-based designs. This framework is validated by comparing the thermal and structural responses of a square hollow section (SHS) steel column under fire with the experimental data. The critical parameters of the fire scenario produced by the framework are found in close agreement with the experimental data. The thermal and structural responses of the SHS column exposed to the developed fire scenario are also validated with test results in terms of structural temperatures, failure modes, and failure load.

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Zhuang J, Payyappalli, Vineet M. Behrendt A, Lukasiewicz K (2017) Total Cost of Fire in the United States

Eurocode I (2002) BS EN 1991–1–2:2002. Eurocode 1: actions of structures - Part 1–2: general actions - actions on structures exposed to fire

Bisby L, Gales J, Maluk C (2013) A contemporary review of large-scale non-standard structural fire testing. Fire Sci Rev 2:1. https://doi.org/10.1186/2193-0414-2-1CrossRef

Khan AA, Usmani AS, Torero JL (2021) Evolution of fire models for estimating structural fire-resistance. Fire Saf J 124:103367CrossRef

Cowlard A, Bittern A, Abecassis-Empis C, Torero J (2013) Fire safety design for tall buildings. Procedia Eng 62:169–181. https://doi.org/10.1016/j.proeng.2013.08.053CrossRef

Stern-Gottfried J, Rein G (2012) Travelling fires for structural design-Part II: design methodology. Fire Saf J 54:96–112CrossRef

Franssen JM (2005) SAFIR: A thermal/structural program for modeling structures under fire. Eng J 42:143–150

Huang Z, Burgess IW, Plank RJ (1999) Nonlinear analysis of reinforced concrete slabs subjected to fire. ACI Struct J 96

Izzuddin BA (1990) Nonlinear dynamic analysis of framed structures. Imperial College, London

10.

Meyer B (1989) Object-oriented software construction. Sci Comput Prog 12:88–90MathSciNetCrossRef

11.

Mcgrattan K, McDermott R, Hostikka S, Floyd J, Vanella M (2019) Fire dynamics simulator technical reference guide volume 1: mathematical Model

12.

McKenna FT (1997) Object-oriented finite element programming: frameworks for analysis, algorithms and parallel computing. University of California, Berkeley

13.

Elhami Khorasani N, Garlock MEM, Quiel SE (2015) Modeling steel structures in Open-Sees: enhancements for fire and multi-hazard probabilistic analyses. Comput Struct 157:218–231CrossRef

14.

Scott MH, Fenves GL, McKenna F, Filippou FC (2008) Software patterns for non-linear beam-column models. J Struct Eng 134:562–571CrossRef

15.

SCI (1991.) Structural fire engineering investigation of Broadgate phase 8 fire

16.

British Steel (1999) The behavior of multi storey steel framed buildings in fire’. A European Joint Research Program

17.

Lennon T, Moore D (2003) The natural fire safety concept—full-scale tests at Cardington. Fire Saf J 38:623–643CrossRef

18.

Franssen JM, Cooke GM, Latham D (1995) Numerical simulation of a full scale fire test on a loaded steel framework. J Constr Steel Res 35:377–408CrossRef

19.

Bailey C (1998) Computer modelling of the corner compartment fire test on the large-scale Cardington test frame. J Constr Steel Res 48:27–45CrossRef

20.

Rose PS, Bailey CG, Burgess IW, Plank RJ (1998) Influence of floor slabs on the structural performance of the Cardington frame in fire. J Constr Steel Res 46:310–311CrossRef

21.

Wang Y (2000) An analysis of the global structural behaviour of the Cardington steel-framed building during the two BRE fire tests. Eng Struct 22:401–412CrossRef

22.

Huang Z, Burgess IW, Plank RJ (2000) Three-dimensional analysis of composite steel-framed buildings in fire. J Struct Eng 126:389–397CrossRef

23.

Elghazouli AY, Izzuddin BA (2004) Realistic modeling of composite and reinforced concrete floor slabs under extreme loading II: verification and application. J Struct Eng 130:1985–1996CrossRef

24.

Khan MA, Jiang L, Cashell KA, Usmani A (2018) Analysis of restrained composite beams exposed to fire using a hybrid simulation approach. Eng Struct 172:956–966. https://doi.org/10.1016/j.engstruct.2018.06.048CrossRef

25.

Khan MA, Jiang L, Cashell KA, Usmani A (2019) Virtual hybrid simulation of beams with web openings in fire. J Struct Fire Eng. https://doi.org/10.1108/JSFE-01-2019-0008CrossRef

26.

Ali Khan M, Cashell KA, Usmani AS (2020) Analysis of Restrained Composite Perforated Beams during Fire Using a Hybrid Simulation Approach. J Struct Eng (United States) 146:1–15. https://doi.org/10.1061/(ASCE)ST.1943-541X.0002528CrossRef

27.

NIST (2005) NIST NCSTAR 1: final report on the collaps of the world trade centre towers

28.

NIST (2008) NIST NCSTAR 1: final report on the collapse of the world trade center building 7

29.

Meacham B, Engelhardt M, Kodur V (2009) Collection of data on fire and collapse. Proc. 2009 NSF Eng. Res. Innov. Conf., Hawaii: Faculty of Architecture Building, Delft University of Technology, p. 1–5

30.

Hajiloo H, Adelzadeh M, Green M (2017) Collapse of Tehran’s Plasco tower in fire. CONFAB 2017, London, p. 338–345

31.

Yarlagadda T, Hajiloo H, Jiang L, Green M, Usmani A (2018) Preliminary modelling of Plasco Tower collapse. Int J High-Rise Build 7:397–408

32.

Khan AA, Domada RVV, Huang X, Khan MA, Usmani A (2021) Modeling the collapse of the Plasco building. Part I: Reconstruction of fire. Build Simul. https://doi.org/10.1007/s12273-021-0825-4 .CrossRef

33.

Khan MA, Khan AA, Usmani AS, Huang X (2021) Can fire cause the collapse of Plasco building: A numerical investigation. Fire Mater. https://doi.org/10.1002/fam.3003CrossRef

34.

Agarwal A, Varma AH (2014) Fire induced progressive collapse of steel building structures: the role of interior gravity columns. Eng Struct 58:129–140CrossRef

35.

Sun R, Huang Z, Burgess IW (2012) Progressive collapse analysis of steel structures under fire conditions. Eng Struct 34:400–413CrossRef

36.

Hidalgo JP, Goode T, Gupta V, Cowlard A, Abecassis-Empis C, Maclean J et al (2019) The Malveira fire test: Full-scale demonstration of fire modes in open-plan compartments. Fire Saf J 108:102827. https://doi.org/10.1016/j.firesaf.2019.102827CrossRef

37.

Gupta V, Hidalgo JP, Cowlard A, Abecassis-Empis C, Majdalani AH, Maluk C et al (2021) Ventilation effects on the thermal characteristics of fire spread modes in open-plan compartment fires. Fire Saf J. https://doi.org/10.1016/j.firesaf.2020.103072CrossRef

38.

Jowsey A (2006) Fire imposed heat fluxes for structural analysis. The University of Edinburgh

39.

Majdalani AH, Cadena JE, Cowlard A, Munoz F, Torero JL (2015) Experimental characterisation of two fully-developed enclosure fire regimes. Fire Saf J 79:10–19. https://doi.org/10.1016/j.firesaf.2015.11.001CrossRef

40.

Kawagoe K, Fire behaviour in rooms - report no. 27 1958

41.

Pettersson O, Magnusson SE, Thor J (1976) Fire engineering design of steel structures. Bulletin 52

42.

Magnusson SE and Thelandersson S (1970) Temperature-time curves of complete process of fire development. Theoretical Study of Wood Fuel Fires in Enclosed Spaces. Civ Eng Build Constr Ser No 65 1970;Acta Polyt

43.

Hasemi Y, Yokobayashi Y, Wakamatsu T, Ptchelintsev AV (1996) Modelling of heating mechanism and thermal response of structural components exposed to localised fires. Thirteenth Meeting of the UJNR Planel on Fire Research and Safety

44.

Rein G, Torero JL, Jahn W, Stern-Gottfried J, Ryder NL, Desanghere S et al (2009) Round-robin study of a priori modelling predictions of the Dalmarnock Fire Test One. Fire Saf J 44:590–602. https://doi.org/10.1016/j.firesaf.2008.12.008CrossRef

45.

Merci B, Beji T (2016) Fluid mechanics aspects of fire and smoke dynamics in enclosures. https://doi.org/10.1201/b21320

46.

Jahn W, Rein G, Torero JL (2011) A posteriori modelling of the growth phase of Dalmarnock Fire Test One. Build Environ 46:1065–1073. https://doi.org/10.1016/j.buildenv.2010.11.001CrossRef

47.

Incropera FP, DeWitt DP, Bergman TL, Lavine AS (2017) Principles of Heat and Mass Transfer, 8th Edition

48.

Jowsey A, Torero J, Lane B (2007) Heat transfer to the structure during the fire. School of Engineering and Electronics, University of Edinburgh, Dalmarnock Fire Tests Exp. Model

49.

Prasad K, Baum HR (2005) Coupled fire dynamics and thermal response of complex building structures. Proc Combust Inst 30:2255–2262. https://doi.org/10.1016/j.proci.2004.08.118CrossRef

50.

Jeffers AE, Beata PA (2014) Generalized shell heat transfer element for modeling the thermal response of non-uniformly heated structures. Finite Elem Anal Des 83:58–67. https://doi.org/10.1016/j.finel.2014.01.003MathSciNetCrossRef

51.

Silva JCG, Landesmann A, Ribeiro FLB (2016) Fire-thermomechanical interface model for performance-based analysis of structures exposed to fire. Fire Saf J 83:66–78. https://doi.org/10.1016/j.firesaf.2016.04.007CrossRef

52.

Zhang C, Silva JG, Weinschenk C, Kamikawa D, Hasemi Y (2016) Simulation methodology for coupled fire-structure analysis: modeling localized fire tests on a steel column. Fire Technol 52:239–262. https://doi.org/10.1007/s10694-015-0495-9CrossRef

53.

Tondini N, Morbioli A, Vassart O, Lechêne S, Franssen JM (2016) An integrated modelling strategy between a CFD and an FE software: methodology and application to compartment fres. J Struct Fire Eng. https://doi.org/10.1108/JSFE-09-2016-015CrossRef

54.

Wickström U (2008) Adiabatic surface temperature and the plate thermometer for calculating heat transfer and controlling fire resistance furnaces. Fire Saf Sci. https://doi.org/10.3801/IAFSS.FSS.9-1227CrossRef

55.

Wickström U, Duthinh D, McGrattan K (2007) Adiabatic surface temperature for calculating heat transfer to fire exposed structures. In: Proc 11th Int Interflam Conf, 2:943–53

56.

Welch S, Miles S, Kumar S, Lemaire T, Chan A (2008) FIRESTRUC - Integrating advanced three-dimensional modelling methodologies for predicting thermo-mechanical behaviour of steel and composite structures subjected to natural fires. Fire Saf Sci. https://doi.org/10.3801/IAFSS.FSS.9-1315CrossRef

57.

Banerjee DK (2014) A software independent tool for mapping thermal results to structural model. Fire Saf J 68:1–15. https://doi.org/10.1016/j.firesaf.2014.06.002CrossRef

58.

Alos-Moya J, Paya-Zaforteza I, Garlock MEM, Loma-Ossorio E, Schiffner D, Hospitaler A (2014) Analysis of a bridge failure due to fire using computational fluid dynamics and finite element models. Eng Struct 68:96–110. https://doi.org/10.1016/j.engstruct.2014.02.022CrossRef

59.

Dai X, Welch S, Vassart O, Cábová K, Jiang L, Maclean J et al (2020) An extended travelling fire method framework for performance-based structural design. Fire Mater 44:437–457. https://doi.org/10.1002/fam.2810CrossRef

60.

Rackauskaite E, Hamel C, Law A, Rein G (2015) Improved formulation of travelling fires and application to concrete and steel structures. Structures 3:250–260. https://doi.org/10.1016/j.istruc.2015.06.001CrossRef

61.

Harmathy TZ (1978) Mechanism of burning of fully-developed compartment fires. Combust Flame 31:265–273. https://doi.org/10.1016/0010-2180(78)90139-6CrossRef

62.

Gupta V, Osorio AF, Torero JL, Hidalgo JP (2020) Mechanisms of flame spread and burnout in large enclosure fires. Proc Combust Inst. https://doi.org/10.1016/j.proci.2020.07.074CrossRef

63.

Thomas PH, Heselden AJM (1972) Fully Developed fires in single compartments. Fire Res Note No 923, Fire Res Station Borehamwood, UK

64.

Khan MA, Khan AA, Usmani AS, Huang X (2021) Can fire cause the collapse of Plasco building: a numerical investigation. Fire Mater

65.

British Steel plc (1999.) The behavior of multi-story steel framed buildings in fire

66.

Kirby BR, Wainman DE, Tomlinson LN, Kay TR, Peacock BN (1999) Natural fires in large scale compartments. Int J Eng Perform Based Fire Codes 1:43–58

67.

Torero JL, Majdalani AH, Abecassis-empis C (2014) Revisiting the compartment fire. https://doi.org/10.3801/IAFSS.FSS.11-28.

68.

Torero JL, Law A, Maluk C (2017) Defining the thermal boundary condition for protective structures in fire. Eng Struct 149:104–112. https://doi.org/10.1016/j.engstruct.2016.11.015CrossRef

69.

FDS. Fire Dynamics Simulator n.d

70.

McGrattan K, Hostikka S, McDermott R, Floyd J, Weinschenk C, Overhold K (2016) Sixth edition fire dynamics simulator user ’s guide (FDS). NIST Spec Publ 1019 2016; Sixth Edit. https://doi.org/10.6028/NIST.SP.1019

71.

OpenSEES. OpenSEES for Fire, http://openseesforfire.github.io/user.html n.d

72.

Orabi MA, Khan AA, Usmani A (2019) An Overview of OpenSEES for Fire. Proc. 1st Eurasian Conf. OpenSEES OpenSEES Days Eurasia, Hong Kong

73.

OpenFIRE. OpenSEES for Fire, http://openseesforfire.github.io/openfire.html n.d. http://openseesforfire.github.io/openfire.html

74.

OpenFIRE (2021) OpenFIRE, https://github.com/aatif85?tab=repositories

75.

Kamikawa D, Hasemi Y, Yamada KN (2006) Mechanical response of a steel column exposed to a localized fire. Proc fourth Int Work stuctures fire, Aveiro, Port, pp 225–234

76.

SFPE (2016) SFPE handbook of fire protection engineering. vol. 5th Editio. https://doi.org/10.1016/s0379-7112(97)00022-2

77.

McGrattan K, Hostikka S, McDermott R, Floyd J, Weinschenk C, Overholt K (2021) Sixth edition fire dynamics simulator technical reference guide volume 3: Validation; 1:1–1077

78.

Jiang J (2012) Nonlinear thermomechanical analysis of structures using OpenSees. University of Edinburgh

79.

Jiang J, Jiang L, Kotsovinos P, Zhang J, Usmani A (2015) OpenSees software architecture for the analysis of structures in fire. J Comput Civ Eng 29:1–13CrossRef

80.

EN 1993–1–2 (2005) Eurocode 3: Design of steel structures - Part 1–2: General rules - Structural fire design. Eur Commitee Stand

81.

Jiang L, Usmani A (2018) Towards scenario fires – modelling structural response to fire using an integrated computational tool. Adv Struct Eng 21:2056–2067. https://doi.org/10.1177/1369433218765832CrossRef

82.

EN-1994–1–2. Eurocode 4: Design of composite steel and concrete structures - Part 1–2 General rules - Structural fire design. Eur Commitee Stand 2005.

Titel: OpenFIRE: An Open Computational Framework for Structural Response to Real Fires
verfasst von: Aatif Ali Khan
Mustesin Ali Khan
Chao Zhang
Liming Jiang
Asif Usmani
Publikationsdatum: 18.10.2021
Verlag: Springer US
Erschienen in: Fire Technology / Ausgabe 2/2022
Print ISSN: 0015-2684
Elektronische ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-021-01184-0

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