Abstract
Vertical arrays of horizontally protruding wood matchsticks, 0.25 cm in diameter and 1.91 cm long, arranged from 1 to 5 matches across were used to investigate the influence of the spacing of discrete fuel elements on rates of upward flame spread. Vertical spacing's between the matchsticks in the array (0.0, 0.6, 0.8, 1.0, 1.2 and 1.4 cm) were used to reveal the influence of separation distance on rates of upward flame spread, defined as progression of the ignition front, time to burnout and mass-loss rates. Advancement of the ignition front was found to vary linearly with time for the 0.0 cm spacing, while reaching nearly a $t^{1.7}$ advancement with time for the furthest-spaced arrays. Rates of upward flame spread were found to increase dramatically for spacings between 0 cm and 0.8 cm and experienced only a slight increase thereafter. Based on these observations, the influence of convective heating was hypothesized to dominate this spread mechanism, and predictions of ignition times were developed using convective heat-transfer correlations. Flame heights and mass-loss rates followed a similar pattern. Individual matchstick burnout times were observed to remain nearly constant for all cases at all heights except the zero-spacing case, which was nearly three times longer than in spaced arrays. This behavior in spaced cases was modeled using a droplet burning theory extended for a cylindrical geometry and solving for the time to burnout. A similar calculation was performed for the zero-spacing case relating it to vertical combustion over a wall. The average mass-loss rate for a single matchstick was also determined and used to predict the mass-loss rate of a spreading fire over matchsticks.
Wednesday, December 21, 2011
New Paper on the Burning Behavior of Vertical Matchstick Arrays Available
Our paper on the Burning Behavior of Vertical Matchstick Arrays, by Michael Gollner, Yanxuan Xie, Minkyu Lee, Yuji Nakamura and Ali Rangwala was recently accepted for publication to the journal Combustion Science and Technology. A pre-print version of the article has been posted here: http://maeresearch.ucsd.edu/~mgollner/publications/2011_matchstick_cst.pdf
Wednesday, October 5, 2011
Mario and Jeanette present their research at the UCSD Summer Research Conference
Jeanette Cobian, a UCSD undergraduate in the UCSD California Louis Stokes Alliance for Minority Participation (CAMP) in Science, Engineering and Mathematics program and Mario Zuniga in the McNair Scholars Program presented their summer research on flame spread and development of a visual flame analysis program. Congratulations on a great presentation and research in the combustion laboratory at UCSD over the summer.
Friday, September 16, 2011
New Grad Students Presentation
Here is a copy of my presentation for new graduate students in the Department of Mechanical and Aerospace Engineering at UCSD. Good luck to new students this year!
The Perfect Firestorm: Interesting Audubon Magazine Feature Article
The Perfect Firestorm
Welcome to the new era of “megafires,” which rage with such intensity that no human force can put them out. Their main causes, climate change and fire suppression, are fueling a heated debate about how to stop them.
By Daniel Glick/Photograph by Larry Schwarm
http://audubonmagazine.org/features1107/GlobalWarming.html#.TnH2RNBbMW0.facebook
Welcome to the new era of “megafires,” which rage with such intensity that no human force can put them out. Their main causes, climate change and fire suppression, are fueling a heated debate about how to stop them.
By Daniel Glick/Photograph by Larry Schwarm
http://audubonmagazine.org/features1107/GlobalWarming.html#.TnH2RNBbMW0.facebook
Thursday, June 30, 2011
Best Poster and Best Fire Science Image Awards at the 10th International Symposium on Fire Safety Science!
The 10th International Symposium on Fire Safety Science was held at the University of Maryland, College Park this past week and brought together an impressive group of scientists and engineers working on today's fire science problems. Before I go on about the conference, a moment of sharing the exciting news that we have won both the Best Poster and Best Fire Science Image Awards! The image, "Fan of Fire" - Surface Inclination Effects on Upward Flame Spread and the poster "An Experimental Study of Upward Flame Spread over Inclined Fuels" with authors Michael J. Gollner, Xinyan Huang, Forman A. Williams, and Ali S. Rangwala won these awards! A description of the image shown is at the bottom and the poster can be viewed here.
"Fan of Fire" – Surface Inclination Effects on Upward Flame Spread
Michael Gollner, Xinyan Huang and Forman A. Williams
University of California, San Diego
Ali S. Rangwala
Worcester Polytechnic Institute
This “fan of fire” visually displays the effect gravity has on upward flame spread over thermally-thick materials. Starting from the left “ceiling fire”, as the inclination angle or tilt of a burning surface is increased underside flames transition from blue, well-mixed laminar flames into increasingly turbulent yellow flames on the topside that “lift” from the surface dramatically increasing the flame thickness. These images were taken perpendicular to the surface of a thick sample of Polymethyl Methacrylate mounted flush into insulation board as flames spread upward. These tests have helped in finding critical inclinations with maximum flame spread rates, burning rates and heat fluxes from the flame.
The conference was an excellent opportunity to interact with researchers in so many different aspects of the fire problem. Prof. Carlos Fernandez-Pello delivered a plenary lecture on ignition of solid fuels, which is a topic that especially resonates with the fire community with the development of new pyrolysis models. It was also great to see a presence from the wildfire research community, culminating with the plenary lecture by Domingos Xavier Viegas. I learned a lot from presentations, but perhaps the most important facet of the conference were the comments, suggestions and ideas I received from fellow researchers. There are too many to name, but I want to thank all those who contributed. I look forward to the next conference in 2014 in New Zeland!
"Fan of Fire" – Surface Inclination Effects on Upward Flame Spread
Michael Gollner, Xinyan Huang and Forman A. Williams
University of California, San Diego
Ali S. Rangwala
Worcester Polytechnic Institute
This “fan of fire” visually displays the effect gravity has on upward flame spread over thermally-thick materials. Starting from the left “ceiling fire”, as the inclination angle or tilt of a burning surface is increased underside flames transition from blue, well-mixed laminar flames into increasingly turbulent yellow flames on the topside that “lift” from the surface dramatically increasing the flame thickness. These images were taken perpendicular to the surface of a thick sample of Polymethyl Methacrylate mounted flush into insulation board as flames spread upward. These tests have helped in finding critical inclinations with maximum flame spread rates, burning rates and heat fluxes from the flame.
Friday, June 17, 2011
Part II of Paper on Commodity Classification Published in the Fire Safety Journal
Part II of our paper, "Warehouse commodity classification from fundamental principles. Part II: Flame heights and flame spread", has recently been published in the Fire Safety Journal. The image at the right shows a research approach to the warehouse fire problem. The two smaller scales studied in this work are shown by the dashed box. You can follow a link to the article at: doi:10.1016/j.firesaf.2011.05.002.
Abstract:
In warehouse storage applications, it is important to classify the burning behavior of commodities and rank them according to their material flammability for early fire detection and suppression operations. In this study, a preliminary approach towards commodity classification is presented that models the early stage of large-scale warehouse fires by decoupling the problem into separate processes of heat and mass transfer. Two existing nondimensional parameters are used to represent the physical phenomena at the large-scale: a mass transfer number that directly incorporates the material properties of a fuel, and the soot yield of the fuel that controls the radiation observed in the large-scale. To facilitate modeling, a mass transfer number (or B-number) was experimentally obtained using mass-loss (burning rate) measurements from bench-scale tests, following from a procedure that was developed in Part I of this paper.
Two fuels are considered: corrugated cardboard and polystyrene. Corrugated cardboard provides a source of flaming combustion in a warehouse and is usually the first item to ignite and sustain flame spread. Polystyrene is typically used as the most hazardous product in large-scale fire testing. The nondimensional mass transfer number was then used to model in-rack flame heights on 6.1–9.1 m (20–30 ft) stacks of ‘C’ flute corrugated cardboard boxes on rack-storage during the initial period of flame spread (involving flame spread over the corrugated cardboard face only). Good agreement was observed between the model and large-scale experiments during the initial stages of fire growth, and a comparison to previous correlations for in-rack flame heights is included.
Part I of this paper has also been published in the Fire Safety Journal and can be found at: doi:10.1016/j.firesaf.2011.03.002
Wednesday, April 27, 2011
Commodity Classification Paper Recently Published in the Fire Safety Journal
The paper, "Warehouse commodity classification from fundamental principles. Part I: Commodity & burning rates" was recently published in the Fire Safety Journal. Check it out here
This paper sets a personal record for length of time from submittal to acceptance and posting. It was submitted in September, 2009 and became available online in April, 2011. A year and a half!
Abstract:
An experimental study was conducted to investigate the burning behavior of an individual Group A plastic commodity over time. The objective of the study was to evaluate the use of a nondimensional parameter to describe the time-varying burning rate of a fuel in complex geometries. The nondimensional approach chosen to characterize burning behavior over time involved comparison of chemical energy released during the combustion process with the energy required to vaporize the fuel, measured by a B-number.
The mixed nature of the commodity and its package, involving polystyrene and corrugated cardboard, produced three distinct stages of combustion that were qualitatively repeatable. The results of four tests provided flame heights, mass-loss rates and heat fluxes that were used to develop a phenomenological description of the burning behavior of a plastic commodity. Three distinct stages of combustion were identified. Time-dependent and time-averaged B-numbers were evaluated from mass-loss rate data using assumptions including a correlation for turbulent convective heat transfer. The resultant modified B-numbers extracted from test data incorporated the burning behavior of constituent materials, and a variation in behavior was observed as materials participating in the combustion process varied. Variations between the four tests make quantitative values for each stage of burning useful only for comparison, as errors were high. Methods to extract the B-number with a higher degree of accuracy and future use of the results to improve commodity classification for better assessment of fire danger are discussed.
This paper sets a personal record for length of time from submittal to acceptance and posting. It was submitted in September, 2009 and became available online in April, 2011. A year and a half!
Abstract:
An experimental study was conducted to investigate the burning behavior of an individual Group A plastic commodity over time. The objective of the study was to evaluate the use of a nondimensional parameter to describe the time-varying burning rate of a fuel in complex geometries. The nondimensional approach chosen to characterize burning behavior over time involved comparison of chemical energy released during the combustion process with the energy required to vaporize the fuel, measured by a B-number.
The mixed nature of the commodity and its package, involving polystyrene and corrugated cardboard, produced three distinct stages of combustion that were qualitatively repeatable. The results of four tests provided flame heights, mass-loss rates and heat fluxes that were used to develop a phenomenological description of the burning behavior of a plastic commodity. Three distinct stages of combustion were identified. Time-dependent and time-averaged B-numbers were evaluated from mass-loss rate data using assumptions including a correlation for turbulent convective heat transfer. The resultant modified B-numbers extracted from test data incorporated the burning behavior of constituent materials, and a variation in behavior was observed as materials participating in the combustion process varied. Variations between the four tests make quantitative values for each stage of burning useful only for comparison, as errors were high. Methods to extract the B-number with a higher degree of accuracy and future use of the results to improve commodity classification for better assessment of fire danger are discussed.
"Fan of Fire" Image Wins 3rd Place at the 2011 Joint Meeting of the Combustion Institute
Our entry into the Combustion Art contest, "Fan of Fire", won 3rd place! Take a look at the image and abstract below, or go to the announcement: http://www.cssci.org/
Third Place — “Fan of Fire - Surface Inclination Effects on Upward Flame Spread”
“This "fan of fire" visually displays the effect gravity has on upward flame spread over thermally-thick materials. Starting from the left "ceiling fire", as the inclination angle or tilt of a burning surface is increased underside flames transition from blue, well-mixed laminar flames into increasingly turbulent yellow flames on the topside that "lift" from the surface dramatically increasing the flame thickness. These images were taken perpendicular to the surface of a thick sample of Polymethyl Methacrylate mounted flush into insulation board as flames spread upward. These tests have helped in finding critical inclinations with maximum flame spread rates, burning rates and heat fluxes from the flame.”
Michael Gollner and Xinyan Huang (University of California, San Diego)
Thursday, February 3, 2011
Research on Combustion of Cardboard Featured by UCSD Jacobs School of Engineering
Work by Gollner, Williams and Rangwala was recently featured by the Jacobs School of Engineering at the University of California, San Diego. The work, assessing the upward flame spread characteristics of corrugated cardboard was recently published in the journal Combustion and Flame.
http://www.jacobsschool.ucsd.edu/news/news_releases/release.sfe?id=1041
San Diego, CA, February 2, 2011--Imagine this: Firefighters enter a several football field-sized, 60-foot high, pitch-black warehouse and they can’t see inside—they don’t know if there is an inferno or a small fire with a lot of smoke. It’s a very dangerous situation, making choices hard. Engineers at UC San Diego have made a breakthrough discovery that could help ease these situations by predicting where and how quickly initial fires spread in warehouses. Results of this research were recently published in a paper called “Upward flame spread over corrugated cardboard” in the journal Combustion and Flame.
Despite many years of research, including the development of analytical and numerical models and extensive experimentation, the complexity of the process of upward flame spread continues to confound the fire-research community.
“Warehouse fires are definitely a big problem,” said Michael Gollner, co-author of the paper and a UC San Diego mechanical and aerospace engineering Ph.D. student. “It has been recently found that fully protected warehouses have burned down and that the sprinkler systems can’t always control the fires. We still don’t understand all the intricacies of this problem.”
In their research, Gollner and his team are focusing on the most commonly used packaging material in warehouses – corrugated cardboard— which has been found to affect predictions of upward flame spread by current descriptions. As part of the study of the combustion of boxes of commodities, rates of upward flame spread during early-stage burning were observed during experiments on wide samples of corrugated cardboard. The research stems from previous experiments Gollner performed focused on the burning of cardboard in collaboration with Ali Rangwala, a professor in the Department of Fire Protection Engineering at the Worcester Polytechnic Institute and a UC San Diego graduate.
“The flame didn’t spread exactly as was assumed so we did some further analysis on how the flame spread on a small scale,” Gollner said. “What we found is that the cardboard, while in the past was assumed to be a solid material, is actually not. There are different layers, and when it burns some of the cardboard actually peels up, so it slows the rate at which fire spreads. This is very important when you are determining how long it takes a fire to reach a sprinkler and trigger a water spray. At the initial phase, that’s when you can actually extinguish a fire most easily. Calculating the sprinkler activation times is really important in designing a warehouse protection system.”
Forman Williams, a UC San Diego mechanical and aerospace engineering professor and co-author of the paper, said the ultimate objective of this research is to help create better classifications of fire hazards in storing commodities and materials in warehouses.
The density and the number of sprinklers they use in a warehouse and the flow rates of sprinklers are determined by the classifications and categories of the packaging material. So we are trying to help determine what the criteria should be,” Williams said.
The engineers’ warehouse fire research, Gollner said, is appealing to the insurance industry and the national regulatory industry, including the National Fire Protection Association, all of which have a big priority in making sure warehouses are safe.
“One of thebiggest concerns is that these systems are designed for firefighter response; they are not made to put themselves out,” Gollner explained. “They are made to contain themselves until firefighters can enter. …Hopefully this will help become a part of new commodity classification standards in the future and in the way warehouses are designed. We hope to allow them to design warehouses safer not only to protect the goods in these warehouses but also the people who work in them and the firefighters who have to respond.”
Next on the researchers’ agenda is to conduct follow-on experiments looking at how fire spreads on surfaces at different angles, a project currently sponsored by the Society of Fire Protection Engineers, Educational and Scientific Foundation.
“We would like to understand better what controls the fire spread in different situations,” Williams said. “There are lots of things we really don’t understand, although fire has been around for a very long time.”
Tuesday, January 18, 2011
Paper on Upward Flame Spread Over Corrugated Cardboard Published in Combustion and Flame
Our recent work on flame spread over corrugated cardboard, with applications related to warehouses has been published in the journal Combustion and Flame. Check out the article and abstract below: http://dx.doi.org/10.1016/j.combustflame.2010.12.005
Upward flame spread over corrugated cardboard
M.J. Gollner, F.A. Williams and A.S. Rangwala
As part of a study of the combustion of boxes of commodities, rates of upward flame spread during early-stage burning were observed during experiments on wide samples of corrugated cardboard. The rate of spread of the flame front, defined by the burning pyrolysis region, was determined by visually averaging the pyrolysis front position across the fuel surface. The resulting best fit produced a power-law progression of the pyrolysis front, xp = At^n, where xp is the average height of the pyrolysis front at time t, n = 3/2, and A is a constant. This result corresponds to a slower acceleration than was obtained in previous measurements and theories (e.g. n = 2), an observation which suggests that development of an alternative description of the upward flame spread rate over wide, inhomogeneous materials may be worth studying for applications such as warehouse fires. Based upon the experimental results and overall conservation principles it is hypothesized that the non-homogeneity of the cardboard helped to reduce the acceleration of the upward spread rates by physically disrupting flow in the boundary layer close to the vertical surface and thereby modifying heating rates of the solid fuel above the pyrolysis region. As a result of this phenomena, a distinct difference was observed between scalings of peak flame heights, or maximum “flame tip” measurements and the average location of the flame. The results yield alternative scalings that may be better applicable to some situations encountered in practice in warehouse fires.
Upward flame spread over corrugated cardboard
M.J. Gollner, F.A. Williams and A.S. Rangwala
As part of a study of the combustion of boxes of commodities, rates of upward flame spread during early-stage burning were observed during experiments on wide samples of corrugated cardboard. The rate of spread of the flame front, defined by the burning pyrolysis region, was determined by visually averaging the pyrolysis front position across the fuel surface. The resulting best fit produced a power-law progression of the pyrolysis front, xp = At^n, where xp is the average height of the pyrolysis front at time t, n = 3/2, and A is a constant. This result corresponds to a slower acceleration than was obtained in previous measurements and theories (e.g. n = 2), an observation which suggests that development of an alternative description of the upward flame spread rate over wide, inhomogeneous materials may be worth studying for applications such as warehouse fires. Based upon the experimental results and overall conservation principles it is hypothesized that the non-homogeneity of the cardboard helped to reduce the acceleration of the upward spread rates by physically disrupting flow in the boundary layer close to the vertical surface and thereby modifying heating rates of the solid fuel above the pyrolysis region. As a result of this phenomena, a distinct difference was observed between scalings of peak flame heights, or maximum “flame tip” measurements and the average location of the flame. The results yield alternative scalings that may be better applicable to some situations encountered in practice in warehouse fires.
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