development of 3d heat transfer and pyrolysis in fds · femtc 2018 3d heat transfer and pyrolysis...
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![Page 1: Development of 3D Heat Transfer and Pyrolysis in FDS · FEMTC 2018 3D Heat Transfer and Pyrolysis in FDS 19 3D Model 1D Model 0 5 10 15 20 25 30 Time (s) 0 0.5 1 1.5 M a s s (k g)](https://reader034.vdocuments.mx/reader034/viewer/2022050422/5f91b48fd0fe444b067679af/html5/thumbnails/1.jpg)
Development of 3D Heat Transfer and Pyrolysis
in FDS
Randall McDermott1, Chao Zhang1, Morgan Bruns2, Salah Benkorichi3
1National Institute of Standards and Technology, Gaithersburg, Maryland, USA2Virginia Military Institute, Lexington, Virginia, USA
3Omega Fire Engineering Ltd., Manchester, UK
Fire and Evacuation Modeling Technical Conference 2018
Oct 1-3, Gaithersburg, Maryland
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Background and Motivation
• Structural analysis
• Lateral and downward flame spread
• Smoldering combustion
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Ohlemiller & Shields, 2008Choe, 2017 Huang et al., 2016
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Previous Work
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• Andreas Vischer, Aachen, 2009 thesis
• Volker Hohm and Matthias Siemon, Building Materials, Solid Construction and Fire Protection (iBMB) at Technische UniverstätBraunschweig
• Gpyro, Chris Lautenberger, Reax Engineering
• Thermakin, Stas Stoliarov, U. Maryland
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Integration into FDS master
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TEMPERATURE SLICE
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Governing Equations
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Local deformation
affects heat flux
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Computing Heat Flux
Fourier’s law:
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Input Parameters
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HT3D=T invokes 2-way coupling with gas phase
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Heat Diffusion in Steel I-Beam
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Any mention of commercial products within this paper is for information only; it does not imply recommendation or endorsement by NIST.
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Internal Heating in Sphere
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• Constant, uniform internal
heat generation
• Constant, ambient surface
temperature
0 0.02 0.04 0.06 0.08 0.1
Radial Distance (m)
20
30
40
50
60
Te
mp
era
ture
(°C
)
FDS6.7.0-515-g7416f3a-master
Analytical
FDS t=10 s
FDS t=20 s
FDS t=60 s
FDS t=120 s
FDS t=180 s
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Density Definitions
1. Material
2. Bulk
3. Total solid
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Modeling Deformation
• Changes in composition generally cause contraction or expansion of material
• Some challenges in 3D:1. Mechanical constitutive relation
2. Advection term in conservation equations
3. Moving boundaries
• Simple solution: 1. Subgrid scale models of fluxes
2. Burn away—remove solid cells as cell density goes to zero
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Heat Flux with Local Deformation
• As material contracts (expands), distance between material points decreases (increases)
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Local Material Deformation
Two simple models:1. Isotropic:
2. Unidirectional:
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Compute new
densities
using old
temperatures
Compute solid
volumes
using new
densities
Compute new
temperatures
using heat
fluxes
Compute heat
fluxes on
solid volumes
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PMMA Slab: Mass Loss Rate and Thickness
0 100 200 300 400 500 600
Time (s)
0
0.01
0.02
0.03
0.04
ML
RP
UA
(kg
/s/m
2)
3D Pyrolysis (pyro3d_vs_pyro1d)
FDS6.7.0-515-g7416f3a-master
PYRO1D (no burn away)
PYRO3D (burn away)
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Time (s)
0
0.002
0.004
0.006
0.008
0.01
0.012
Th
ickn
ess (
m)
3D Pyrolysis (pyro3d_vs_pyro1d)
FDS6.7.0-515-g7416f3a-master
PYRO1D (no burn away)
PYRO3D (burn away)
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Radiative Heat Transfer
• Many problems are thermally thick
• Diffusion approximation is extremely efficient in 3D
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Material Absorption Coefficient (1/m) Thermal Thickness for 1 cm slab
HDPE 1300 13
PMMA 2700 27
PA66 3920 39.2
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Radiation Verification
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Exact solution from Modest,
Radiative Heat Transfer, 2nd
Edition.0 0.02 0.04 0.06 0.08 0.1
x (m)
0
200
400
600
800
Tem
pera
ture
(°C
)
HT3D Internal Radiation (ht3d_radiation)
FDS6.7.0-610-g8606b24-master
Exact =100 1/m
FDS =100 1/m Nx=10
FDS =100 1/m Nx=20
FDS =100 1/m Nx=40
Exact =2000 1/m
FDS =2000 1/m Nx=10
FDS =2000 1/m Nx=20
FDS =2000 1/m Nx=40
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Pyrolysis Gas Transport
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?
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Burn Away• 40 cm cubes
• Low density “foam”
• Compartment walls at 1100 °C
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3D Model 1D Model
0 5 10 15 20 25 30
Time (s)
0
0.5
1
1.5
Mass (
kg)
Pyrolyzed Mass (box_burn_away1)
FDS6.7.0-534-g33dc811-master
Ideal
PYRO1D (fuel)
PYRO3D (fuel)
PYRO3D w/ transport (fuel)
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Solid Sub-Surface Heat Flux Model
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Closing remarks
• Development of an efficient 3D pyrolysis model is needed for reliable predictions of flame spread (work in progress)
• Subgrid-scale models of heat and mass fluxes were used to account for local deformation
• The resultant model has been verified and tested for several scenarios
• Next steps:• Anisotropy• Thin obstructions (coupling with 1D model?)• Porous media flow
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Acknowledgements
• FDS development team
• Simo Hostikka, Deepak Paudel
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