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07-11-2019

Development of a Fluid–Structure Coupling Validated with a Confined Fire: Application to Painted Caves

Authors: Fabien Salmon, Delphine Lacanette, Jean-Christophe Mindeguia, Colette Sirieix, Axel Bellivier, Jean-Claude Leblanc, Catherine Ferrier

Published in: Fire Technology | Issue 3/2020

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Abstract

In 1994, three speleologists discovered the Chauvet–Pont d’Arc Cave, which contains singular thermal marks on walls deep in the cavity. These alterations arose from intense fires, and understanding their characteristics would help archaeologists suggest hypotheses about the function of such activities. In this context, three confined fires were conducted in a former underground quarry to reproduce thermo-alterations similar to those in the Chauvet–Pont d’Arc Cave and extract experimental data. Each fire involved approximately 135 kg of wood, which was continuously supplied by firemen for safety reasons (> 500°C) and burnt in the shape of a tepee 80 cm in diameter for 50 min. This paper presents the validation of a numerical model on this experimentation. The modelling requires coupling between the combustion and wall impact simulations. Thus, a link between the combustion code FireFOAM and the thermo-mechanical code Cast3m was created with Python scripts. The results from the simulation agree with the measurements and the observations. More specifically, the analysis is based on the temperatures, gas and particle concentrations, gas velocities, soot deposition, colour changes at the walls and areas likely to spall. These data were collected from thirty-seven measuring points covering the whole quarry. This validated tool will provide information about the features of the fires that occurred within the Chauvet–Pont d’Arc Cave.

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Zadeh S, Maragkos G, Beji T, Merci B (2016) Large eddy simulation of the ceiling jet induced by the impingement of a turbulent air plume. Fire Technol 52(6):2093–2115

Le D, Labahn J, Beji T, Devaud C, Weckman E, Bounagui A (2018) Assessment of the capabilities of FireFOAM to model large-scale fires in a well-confined and mechanically ventilated multi-compartment structure. J Fire Sci 36(1):3–29

Yuan S, Zhang J (2009) Large eddy simulation of compartment fire with solid combustibles. Fire Saf J 44(3):349–362MathSciNet

Weisenpacher P, Glasa J, Halada L (2016) Parallel Computation of smoke movement during a car park fire. Comput Inform 35:1416–1437MathSciNetMATH

Zhang X, Guo Y, Chan C, Lin W (2007) Numerical simulations on fire spread and smoke movement in an underground car park. Build Environ 42(10):3466–3475

Roh J, Ryou H, Kim D, Jung W, Jang Y (2007) Critical velocity and burning rate in pool fire during longitudinal ventilation. Tunn Undergr Space Technol 22(3):262–271

Zhao S, Liu F, Wang F, Weng M, Zeng Z (2018) A numerical study on smoke movement in a metro tunnel with a non-axisymmetric cross-section. Tunn Undergr Space Technol 73:187–202

McGrattan K, Hostikka S, McDermott R, Floyd J, Weinschenk C, Overholt K (2013) Fire dynamics simulator user’s guide, sixth edition 1019. NIST Special Publication (Online). https://pages.nist.gov/fds-smv/manuals.html

Li J, Chow W (2003) Numerical studies on performance evaluation of tunnel ventilation safety systems. Tunn Undergr Space Technol 18(5):435–452

10.

Meng N, Hu L, Wu L, Yang L, Zhu S, Chen L, Tang W (2014) Numerical study on the optimization of smoke ventilation mode at the conjunction area between tunnel track and platform in emergency of a train fire at subway station. Tunn Undergr Space Technol 40:151–159

11.

Zhao B, Kruppa J (2002) Structural behaviour of an open car park under real fire scenarios. Fire Mater 28:269–280

12.

Luo C, Xie W, DesJardin P (2011) Fluid–structure simulations of composite material response for fire environments. Fire Technol 47(4):887–912

13.

Khoury G (2000) Effect of fire on concrete and concrete structures. Prog Struct Eng Mater Banner 2(4):429–447

14.

Zhang H, Davie C (2013) A numerical investigation of the influence of pore pressures and thermally induced stresses for spalling of concrete exposed to elevated temperatures. Fire Saf J 59:102–110

15.

Bordard A, Guibert P, Ferrier C, Debard E, Kervazo B, Geneste J (2014) Les rubéfactions des parois de la grotte Chauvet: une histoire de chauffe? In: Les arts de la Préhistoire: micro-analyses, mises en contextes et conservation, Paillet P. (dir)

16.

Debard E, Ferrier C, Kervazo B (2012) Etude géologique de la grotte Chauvet–Pont d’Arc. Bilan des travaux de la triennale 2010–2012. Etudes pluridisciplinaires à la grotte Chauvet–Pont d’Arc (Ardèche). Rapport d’activité 2010–2012, vol 1, pp 59–98

17.

Quiles A, Valladas H, Bocherens H, Delque-Kolic E, Kaltnecker E, Plicht J, Delannoy J-J, Feruglio V, Fritz C, Monney J, Philippe M, Tosello G, Clottes J, Geneste J-M (2016) A high-precision chronological model for the decorate Upper Paleolithic cave of Chauvet–Pont d’Arc, Ardèche, France. Proc Natl Acad Sci 113(17):4670–4675

18.

Guibert P, Brodard A, Quilès A, Geneste J-M, Baffier D, Debard E, Ferrier C (2015) When were the walls of the Chauvet–Pont-d’Arc Cave heated? A chronological approach by thermoluminescence. Quat Geochronol 29:36–47

19.

Ferrier C, Debard E, Kervazo B, Brodard A, Guibert P, Baffier D, Feruglio V, Gely B, Geneste J, Maksud F (2014) Les parois chauffées de la grotte Chauvet–Pont d’Arc (Ardèche): caractérisation et chronologie. Paléo 25:59–78

20.

Lacanette D, Mindeguia J-C, Brodard A, Ferrier C, Guibert P, Leblanc J-C, Malaurent P, Sirieix C (2017) Simulation of an experimental fire in an underground limestone quarry for the study of Paleolithic fires. Int J Therm Sci 120:1–18

21.

Salmon F, Lacanette D, Mindeguia J-C, Sirieix C, Ferrier C, Leblanc J-C (2018) FireFOAM simulation of a localised fire in a gallery. J Phys Conf Ser 1107, 042017

22.

Salmon F, Lacanette D, Mindeguia J-C, Sirieix C, Bellivier A, Ferrier C, Leblanc J-C (2019) Localized fire in a gallery: model development and validation. Int J Therm Sci 139:144–159

23.

OpenFOAM (Online). http://www.openfoam.org/

24.

FireFOAM (Online). http://www.fmglobal.com/modeling

25.

CAST3M (2016) (Online). http://www-cast3m.cea.fr

26.

Théry-Parisot I, Thiébault S (2005) Analyses polliniques des sols aurignaciens de la grotte Chauvet (Ardèche). In: Geneste (dir) J-M (ed) La grotte Chauvet à Vallon-Pont-d’Arc: un bilan des recherches pluridisciplinaires. Actes de la séance de la Société préhistorique française, Lyon, 2003, Paris

27.

Bellivier A, Coppalle A, Loo A, Yon J, Decoster L, Dupont S, Bazin H (2015) Comparison and assessment of particle mass concentrations measurements in fire smokes with a microbalance, opacimeter and PPS devices. In: 10th AOSFST, October 5–7, Tsukuba

28.

Luo M (1997) Effects of radiation on temperature measurement in a fire environment. J Fire Sci 15(6):443–460

29.

Dréan V, Auguin G, Leblanc J-C, Lacanette D, Mindeguia J-C, Bellivier A, Ferrier C (2017) Numerical modelling of thermal conditions during fires in cave-like geometry. In: Proceedings of the 15th international conference fire and materials, pp 64–65

30.

Chase J (1998) NIST-JANAF thermochemical tables, fourth edition. J Phys Chem Ref Data, Mongraph No. 9

31.

Poling B, Prausnitz J, O’Connell J (1987) The properties of gases and liquids. McGraw-Hill, New York

32.

Sutherland W (1893) The viscosity of gases and molecular force. Philos Mag S5:507–531MATH

33.

Magnussen B, Hjertager B (1977) On mathematical modeling of turbulent combustion with special emphasis on soot formation and combustion. Proc Combust Int 16:719–729

34.

Yoshizawa A (1986) Statistical theory for compressible turbulent shear flows, with the application to subgrid modeling. Phys Fluids 29(7):2152–2164MATH

35.

Tihay V, Perez-Ramirez Y, Morandini F, Santoni P, Barboni T (2013) Heat transfers and energy released in the combustion of fine vegetation fuel beds. 21ème Congrès Français de mécanique

36.

Grosshandler W (1993) A narrow-band model for radiation calculations in a combustion environment. NIST technical note 1402

37.

Beresnev S, Chernyak V (1995) Thermophoresis of s spherical particle in a rarefied gas: numerical analysis based on the model kinetic equations. Phys Fluids 7:1743–1756MATH

38.

Sagot B, Antonini G, Buron F (2009) Annular flow configuration with high deposition efficiency for the experimental determination of thermophoretic diffusion coefficients. J Aerosol Sci 40(12):1030–1049

39.

Brugière E (2012) PhD thesis, INSA (Rouen)

40.

SnappyHexMesh (Online). https://openfoam.org/?s=snappyhexmesh

41.

Alpert R (2008) SPFE handbook of fire protection engineering, Chapter Ceiling Jet Flows, 4th edn. National Fire Protection Association, Quincy

42.

You H, Faeth G (1979) Ceiling heat transfer during fire plume and fire impingement. Fire Mater 3(3):140–147

43.

Holman J (1990) Heat transfer, 7th edn. McGraw-Hill, New York

44.

Vilfayeau S, Ren N, Wang Y, Trouvé A (2015) Numerical simulation of under-ventilated liquid-fueled compartment fires with flame extinction and thermally-driven fuel evaporation. Proc Combust Inst 35(3):2563–2571

45.

Maragkos G, Beji T, Merci B (2017) Advances in modelling in CFD simulations of turbulent gaseous pool fires. Combust Flame 181:22–38

46.

Le V, Marchand A, Verma S, White J, Marshall A, Rogaume T, Richard F, Luche J, Trouvé A (2018) Simulations of a turbulent line fire with a steady flamelet combustion model and non-gray gas radiation models. J Phys Conf Ser 1107:042009

47.

Chatterjee P, Meredith K, Wang Y (2017) Temperature and velocity distributions from numerical simulations of ceiling jets under unconfined, inclined ceilings. Fire Saf J 91:461–470

48.

Ren N, Wang Y, Vilfayeau S, Trouvé A (2016) Large eddy simulation of turbulent vertical wall fires supplied with gaseous fuel through porous burners. Combust Flame 169:194–208

49.

Cooper L (1988) Ceiling jet-driven wall flows in compartment fires. Combust Sci Technol 62(4–6):285–296

50.

McCaffrey B, Heskestad G (1976) A robust bidirectional low-velocity probe for flame and fire application. Combust Flame 26:125–127

51.

Overholt K, Floyd J, Ezekoye O (2016) Computational modeling and validation of aerosol deposition in ventilation ducts. Fire Technol 52(1):149–166

52.

Coupling OpenFOAM—Cast3m (2019) (Online). https://github.com/FabienSalmon/Couplage.git

53.

Liedgren L, Hörnberg G, Magnusson T, Östlund L (2017) Heat impact and soil colors beneath hearths in northern Sweden. J Archaeol Sci 79:62–72

54.

Aldeias V, Dibble H, Sandgathe D, Goldberg P, McPherron S (2016) How heat alters underlying deposits and implications for archaeological fire features: a controlled experiment. J Archaeol Sci 67:64–79

55.

Ruan H, Frost R, Kloprogge J, Duong L (2002) Infrared spectroscopy of goethite dehydroxylation: III. FT-IR microscopy of in situ study of the thermal transformation of goethite to hematite. Spectrochim Acta Part A 58:967–981

56.

Borg R, Hajpal M, Török A (2013) The fire performance of limestone, vol 6. Application of Structural Fire Engineering

57.

58.

Preston F, White H (1938) Observations on spalling. J Am Ceram Soc 17:137–144

59.

Geuzaine C, Remacle J (2009) Gmsh: a 3-D finite element mesh generator with built-in pre- and post-processing facilities. Int J Numer Methods Eng 79(11):1309–1331MathSciNetMATH

Title: Development of a Fluid–Structure Coupling Validated with a Confined Fire: Application to Painted Caves
Authors: Fabien Salmon
Delphine Lacanette
Jean-Christophe Mindeguia
Colette Sirieix
Axel Bellivier
Jean-Claude Leblanc
Catherine Ferrier
Publication date: 07-11-2019
Publisher: Springer US
Published in: Fire Technology / Issue 3/2020
Print ISSN: 0015-2684
Electronic ISSN: 1572-8099
DOI: https://doi.org/10.1007/s10694-019-00926-5

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