Ignition from the Condensed PhaseIgnition from the Condensed Phase Alexander L. Brown;...
Transcript of Ignition from the Condensed PhaseIgnition from the Condensed Phase Alexander L. Brown;...
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Sandia National Laboratories is a multi-program laboratory managed and operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin
Corporation, for the U.S. Department of Energy’s National Nuclear Security Administration under contract DE-AC04-94AL85000.
Ignition from the Condensed Phase
Alexander L. Brown; [email protected]; (505)844-1008Fire Science and Technology Department
With contributions from Jeff Engerer and Ethan Zepper
SAND2017-5965 C
MaCFP Working Group on Condensed Phase PhenomenaJune 11, 2017, Lund, Sweden
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Outline1. Overview of current work by the Sandia fire group
2. Historical ignition for High Heat Flux
3. Active testing at Sandia (facility overview)
4. Recent test results overview
5. Modeling introduction
6. Summary and path forward
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Current SNL Activities Ongoing experimental work at Sandia
Solid reacting material validation work (Kate Hoffmeister)
Using thermophosphors to probe surface temperatures
Create detailed validation datasets for solid reacting material model validation
High heat flux ignition testing in three facilities:
Solar furnace
Solar tower
Large Blast Thermal Simulator
Aircraft damage assessments to high heat flux (Rachel Colbert)
Simulation campaigns relating to solar furnace datasets SIERRA/Aria
SIERRA/Fuego
Gpyro
Rubble fire (mixed solid and liquid fuels) 3
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High Heat Flux Ignition Why we care?-we seek to be able to adequately plan,
predict and respond to NW events
Bombs dropped on Japan provide some data
Hiroshima-Major fire damage, firestorm developed
Nagasaki-Fires generally not considered significant source of damage
US and other countries’ test programs provide data
Our current sense is these data are not as significant and usable as they could have been (lack of details, weak environment information)
Limited to test locations (no forested or similar areas)
Prior testing to replicate the environment at lab scale
S.B. Martin and collaborators, USN tests, mostly 1950-1970
Some blast-fire interaction work 1975-1985
Almost nothing intentionally for NW since
Many modeling efforts4
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Current Ignition Literature Ignition Handbook (Babruskas, 2003)
Cites Glasstone and Dolan (1977) as main source
We believe their ignition data are based on the historical data from the 50’s-60’s.
SFPE Handbook (Sec. 2-11) Ignition section written by Kanury, heavily references
Martin’s work
“Martin and his collaborators had honed the technique of ignition measurement to such a fine art that their measured ignition thresholds of drapes, typing paper, dry rotted wood and leaves were included in the newer printing of Glasstone’sEffects of Nuclear Weapons”—Kanury, A. M. (2009). SFPE Classic
Paper Review: Diffusion-Controlled Ignition of Cellulosic Materials by Intense Radiant Energy by Stanley B. Martin. Journal of Fire Protection Engineering, 19(2), 125-131.
Most current recommendations for high flux ignition go back to the same dated sources
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Martin’s Regimes of Ignition
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Martin S.B., Diffusion-controlled ignition of cellulosic materials by intense radiant energy. In
Symposium (International) on Combustion 1965 Jan 1 (Vol. 10, No. 1, pp. 877-896). Elsevier.
• Maps ignition regimes for cellulose
• Has units of temperature (K)
• Based on black α-cellulose paper using square flux waves
• Recommended in the SFPE handbook
• Diagonal lines (45º) are constant Fourier numbers
• Massive testing contributed to the map
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Fire Test Facilities SNL Solar Furnace
Relevant fluxes at 10 cm-scale spot
Relatively agile for testing
Solar Tower Relevant fluxes at meter-scale spot
Field of heliostat mirrors
Moderately agile for testing
LBTS Combines blast and fire
Commissioning underway
Need to design fire initiation methods, a topic of current effort
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Solar Furnace Test Results
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Comparison to Martin: Organics
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Total Quantities
-Preliminary-
Time-of-Ignition Quantities
-Preliminary-
Fabric and green needles do not ignite
Wood, fabric ignite later than Martin’s cellulose
All data points are for transient flaming (other than Dry Needles)
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Comparison to Martin: Polymers
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Total Quantities
-Preliminary-
Time-of-Ignition Quantities
-Preliminary-
PMMA is more difficult to ignite
Many ignite similar to cellulose
All data points are for transient flaming
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Solar Tower Test Video
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Recent Experimental Findings Ignition thresholds are different at different scale
Solar tower and solar furnace ignition flux/fluences vary significantly (at least a factor of 3)
Organics tend to form char towards the end of the test Early char formation is less significant
Martin’s map reasonably predicts ignition for many materials Some exceptions
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Temperature
Irradiation
SIERRA Coupled-Mechanics ExampleObject-in-Fire with Structural Response
Syrinx
Participating
Media
Radiationn(n+2) dof/node
SIERRA
Transfer
of nodal variables
(interpolation)
SURFACEAria
Conduction
Heat Transfer,
Enclosure Radiation1 dof/node
+ chemistry
Fuego
Turbulent
Fluid Mechanics,
Combustion15 dof/node
Adagio
Quasi-Statics
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Current Modeling Activities SIERRA/Fuego (1-D surface and particle reaction models) used to model
solar furnace and solar tower material response
SIERRA/Aria is being explored for modeling tests (3D capability)
Gpyro is being used to simulate tests
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Wildland fire with firebrands predicted with
SIERRA/Fuego
Predicted response of a PMMA sample to the
solar furnace test conditions
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Summary Sandia is actively evaluating material response to high heat
flux for fire events
Modeling and simulation efforts are in progress
We are trying to determine the need for reaction kinetics at the high heat flux conditions
Char formation, kinetics, and material properties are topics of interest
We are interested in contributing to a community effort to validate this type of models
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Acknowledgements The Sandia experimental team, Ryan Anderson, Michael
Bejarano, Josh Christian, Deshawn Coombs, Alvaro Cruz-Cabrera, Byron Demosthenous, Jeff Engerer, Bill Kolb, Doug Robb, Richard Simpson, Leland Sharp, Anthony Tanbakuchi, Dan Worley
USMA NSERC support from Maj. Andrew Decker, Cdt. Noah Siegel, Cdt. Bobby Thomas
Programmatic and collaborative support from the DTRA/ARA/IDA teams (McAninch, O’Hara, Crepeau, Wiri, Dolph), John Rogers, Karen Rogers, Steve Schafer at SNL
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Additional Content
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Fabric Asphalt Shingles Wood Shingles Polycarbonate
Dry Needles Green Needles Lumber Epoxy Fiber
Cellulose PMMA Polystyrene Paper
Tire Tread Tire Sidewall Painted Aluminum Asphalt
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Fabric Asphalt Shingles Wood Shingles Polycarbonate
Dry Needles Green Needles Lumber Epoxy Fiber
Cellulose PMMA Polystyrene Paper
Tire Tread Tire Sidewall Painted Aluminum Asphalt
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Variable Cellulose Decomposition Rate
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From Milosavljevic and Suuberg, Ind. Eng. Chem. Res., 34, 1081-1091, 1995:
Kinetics for heating rates >10 K/min Kinetics for heating rates <10 K/min
Kinetics depend on rates of heating!
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Solar Tower Test Results
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Similar flux and fluence as at the solar furnace, except larger scale
Green needles and PMMA ignited at the tower, did not in the furnace
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TP1 Results
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TP2 Results
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TP3 Results
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