Title: Flammable and Combustible Liquid Spill/Burn Patterns.
Series: Law Enforcement and Corrections Standards and Testing Program
Authors: Anthony D. Putorti Jr., Jay A. McElroy, and Daniel
Madrzykowski
Published: National Institute of Justice, March 2001
Subject: Criminal investigation
18 pages
38,000 bytes

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U.S. Department of Justice
Office of Justice Programs
National Institute of Justice

National Institute of Justice
Law Enforcement and Corrections Standards and Testing Program

Flammable and Combustible Liquid Spill/Burn Patterns
NIJ Report 604-00

-------------------------------

ABOUT THE LAW ENFORCEMENT AND CORRECTIONS
STANDARDS AND TESTING PROGRAM

The Law Enforcement and Corrections Standards and Testing Program is
sponsored by the Office of Science and Technology of the National
Institute of Justice (NIJ), U.S. Department of Justice. The program
responds to the mandate of the Justice System Improvement Act of 1979,
which directed NIJ to encourage research and development to improve the
criminal justice system and to disseminate the results to Federal, State, and
local agencies.

The Law Enforcement and Corrections Standards and Testing Program is
an applied research effort that determines the technological needs of
justice system agencies, sets minimum performance standards for specific
devices, tests commercially available equipment against those standards,
and disseminates the standards and the test results to criminal justice
agencies nationally and internationally.

The program operates through:

The Law Enforcement and Corrections Technology Advisory Council
(LECTAC), consisting of nationally recognized criminal justice
practitioners from Federal, State, and local agencies, which assesses
technological needs and sets priorities for research programs and items to
be evaluated and tested.

The Office of Law Enforcement Standards (OLES) at the National
Institute of Standards and Technology, which develops voluntary national
performance standards for compliance testing to ensure that individual
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standards are based upon laboratory testing and evaluation of
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and analyze data. Test results are published in Equipment Performance
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also available online through the Internet/World Wide Web. To request a
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National Law Enforcement and Corrections Technology Center
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Rockville, MD 20849-1160
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-------------------------------

U.S. Department of Justice
Office of Justice Programs
National Institute of Justice

Flammable and Combustible Liquid Spill/Burn Patterns
NIJ Report 604-00

Anthony D. Putorti, Jr.
Fire Safety Engineering Division
Building and Fire Research Laboratory
National Institute of Standards and Technology
Gaithersburg, MD 20899-8641

Prepared for:

National Institute of Justice
Office of Science and Technology
Washington, DC 20531

March 2001

NCJ 186634

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National Institute of Justice

The technical effort to develop this report was conducted under
Interagency Agreement 94-IJ-R-004, Project No. 96-002. This report was
prepared with the assistance of the Office of Law Enforcement Standards
(OLES) of the National Institute of Standards and Technology (NIST)
under the direction of Kathleen M. Higgins, Director of OLES. The work
resulting from this report was sponsored by the National Institute of
Justice (NIJ), Dr. David G. Boyd, Director, Office of Science and
Technology.

-------------------------------

FOREWORD

The Office of Law Enforcement Standards (OLES) of the National
Institute of Standards and Technology (NIST) furnishes technical support
to the National Institute of Justice (NIJ) program to strengthen law
enforcement and criminal justice in the United States. OLES's function is
to conduct research that will assist law enforcement and criminal justice
agencies in the selection and procurement of quality equipment.

OLES is: (1) Subjecting existing equipment to laboratory testing and
evaluation, and (2) conducting research leading to the development of
several series of documents, including national standards, user guides, and
technical reports.

This document covers research conducted by OLES under the sponsorship
of the National Institute of Justice. Additional reports as well as other
documents are being issued under the OLES program in the areas of
protective clothing and equipment, communications systems, emergency
equipment, investigative aids, security systems, vehicles, weapons, and
analytical techniques and standard reference materials used by the forensic
community.

Technical comments and suggestions concerning this report are invited
from all interested parties. They may be addressed to the Office of Law
Enforcement Standards, National Institute of Standards and Technology,
100 Bureau Drive, Stop 8102, Gaithersburg, MD 20899-8102.

Dr. David G. Boyd, Director
Office of Science and Technology
National Institute of Justice

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CONTENTS

FOREWORD
COMMONLY USED SYMBOLS AND ABBREVIATIONS

1. INTRODUCTION

2. ANALYTICAL SPILL SIZE PREDICTION

3. SPILL AREA

4. SPILL IGNITION EXPERIMENTS
o 4.1 Nonporous Surfaces
o 4.2 Carpeted Surfaces

5. ANALYSIS AND RESULTS
o 5.1 Spill and Burn Areas
o 5.2 Peak Heat Release Rate
o 5.3 Heat Release Rate Per Unit Area

6. CONCLUSIONS

7. REFERENCES

APPENDIX A--HEAT RELEASE RATES

TABLES

Table 1. Physical properties of spilled fuels
Table 2. Spill thickness predictions
Table 3. Comparison of predicted and empirically derived spill thickness
Table 4. Carpet flooring composition
Table 5. Carpet spill areas
Table 6. Gasoline fire experimental matrix
Table 7. Nonporous spill fire and pool fire HRR
Table 8. Carpet spill fire and pool fire HRR

FIGURES

Figure 1. Fuel pour apparatus. The dimension "A" is 510 mm +/- 10 mm.
The container opening diameter and volume are approximate

Figure 2. Infrared image of gasoline spill on wood parquet floor

Figure 3. Infrared image of gasoline on vinyl tile floor

Figure 4. Gasoline spill fire under the furniture calorimetry hood in the
large Fire Research Laboratory at NIST

Figure 5. Ignition of 1000 mL gasoline spill on wood parquet flooring

Figure 6. Burning in the cracks of the parquet flooring

Figure 7. Burning in the seams of the vinyl tile flooring

Figure 8. 1000 mL gasoline spill fire burn pattern on wood parquet floor

Figure 9. Close-up of gasoline spill fire burn pattern on wood parquet floor

Figure 10. 1000 mL gasoline spill fire pattern on vinyl tile floor

Figure 11. Close-up of gasoline spill fire pattern on vinyl floor

Figure 12. Close-up of gasoline spill fire burn pattern on vinyl floor. Photo
shows the retreat of the tiles at the intersections

Figure 13. Vinyl tile removed after a 1000 mL gasoline spill fire. Damage
to the fiberboard is limited to the vinyl tile seam locations

Figure 14. 1000 mL kerosine spill burn pattern

Figure 15. 1000 mL gasoline spill fire on carpet 1 at approximately 10 s

Figure 16. 1000 mL gasoline spill fire on carpet 1 at approximately 100 s

Figure 17. 1000 mL gasoline spill fire on carpet 2 at approximately 10 s

Figure 18. 1000 mL gasoline spill fire on carpet 2 at approximately 100 s

Figure 19. Close-up view of 250 mL gasoline fire on carpet 1

Figure 20. Close-up view of 250 mL gasoline fire on carpet 1

Figure 21. Doughnut burn pattern on carpet 1. 250 mL gasoline fire,
extinguished at approximately 146 s with CO[2]

Figure 22. Doughnut burn pattern on carpet 1. 1000 mL gasoline fire,
extinguished at approximately 111 s with CO[2]

Figure 23. Doughnut burn pattern on carpet 2. 250 mL gasoline fire,
extinguished at approximately 171 s with CO[2]. Exposed padding can be
seen in the center and toward the left side of the pattern

Figure 24. Doughnut burn pattern on carpet 2. 1000 mL gasoline fire,
extinguished at approximately 1763 s (approximately 30 min) with CO[2]

Figure 25. Carpet padding intact inside the doughnut pattern. 500 mL
gasoline spill fire on carpet 2. Fire was extinguished at approximately 234
s with CO[2]

Figure 26. 1000 ML gasoline spill fire on carpet 2 at approximately 600 s.
This fire yielded the pattern shown in figure 24

Figure 27. Carpet and padding removed from floor leaving doughnut
pattern behind results shown for 250 mL gasoline spill on carpet 1,
extinguished with CO[2] after approximately 213 s of burning

Figure 28. Gasoline spill and burn pattern areas on wood parquet floors

Figure 29. Gasoline spill and burn pattern areas on vinyl tile floors

Figure 30. Gasoline spill and initial burn areas on carpet covered floors

Figure 31. Peak heat release rates for gasoline spills on wood parquet and
vinyl tile floors

Figure 32. Peak heat release rates for gasoline spills on carpet covered
floors

Figure 33. Average peak heat release rate per unit area for gasoline spill
fires on wood parquet and vinyl tile floors

Figure 34. Average peak heat release rate per unit for gasoline spill fires
on carpeted floors

Figure A1. Heat release rates for 250 mL gasoline spill fires on wood
parquet floors

Figure A2. Heat release rates for 500 mL gasoline spill fires on wood
parquet floors

Figure A3. Heat release rates for 1000 mL gasoline spill fires on wood
parquet floors

Figure A4. Heat release rates for 250 mL gasoline spill fires on vinyl tile
flooring

Figure A5. Heat release rates for 500 mL gasoline spill fires on vinyl tile
flooring

Figure A6. Heat release rates for 1000 mL gasoline spill fires on vinyl tile
flooring

Figure A7. Heat release rates for 250 mL spill fires on carpet 1

Figure A8. Heat release rates for 500 mL spill fires on carpet 1

Figure A9. Heat release rates for 1000 mL gasoline spill fires on carpet 1

Figure A10. Heat release rates of 250 mL gasoline spill fires on carpet 2

Figure A11. Heat release rates for 500 mL gasoline spill fires on carpet 2

Figure A12. Heat release rates of 1000 mL gasoline spill fires on carpet 2

-------------------------------

NIJ Report 604-00

Flammable and Combustible Liquid Spill/Burn Patterns

Anthony D. Putorti Jr.
Jay A. McElroy
Daniel Madrzykowski

Fire Safety Engineering Division, Building and Fire Research Laboratory
National Institute of Standards and Technology, Gaithersburg, MD 20899-
8641

Discussions with fire investigators indicate that it would be beneficial to
have the ability to predict the quantity of liquid fuel necessary to create a
burn pattern of a given size. Full-scale spill and fire experiments were
conducted with gasoline and kerosene on vinyl, wood parquet, and carpet
covered plywood floors using various quantities of fuel. Spill areas were
measured, and for nonporous floors the results were compared to
analytical predictions. Burn pattern areas are correlated with the spill
areas, resulting in a method for predicting the quantity of spilled fuel
required to form a burn pattern of a given size. The heat release rates of
the fuel spill fires were determined through experiment and compared to
an existing reference for burning liquid pools of the same surface area. The
peak spill fire heat release rates for nonporous surfaces were found to be
approximately 1/8 to 1/4 of those from equivalent area pool fires. The
peak heat release rates for spill fires on carpet were found to be
approximately equal to those from equivalent area pool fires. The heat
release rates can be used as inputs for fire modeling or for evaluating fire
scenarios.

Key words: accelerants; arson; building fires; burn patterns; carpets; char;
charring; fire investigations; fire measurements; flammable liquids; floors;
floor coverings; heat release rate; pour patterns; spill fires. 

1. INTRODUCTION

Discussions with fire investigators indicate that it would be beneficial to
have the ability to predict the quantity of liquid fuel necessary to create a
burn pattern of a given size. Past studies conducted with liquid fuels
contained too many variables to determine the relationship between spill
quantity and burn pattern area. In an effort to reduce the variables
involved, and thereby understand the process of pattern formation,
experiments are conducted in the laboratory under an instrumented
exhaust hood, without a room or enclosure. This layout would represent a
fire burning in a large space, or in an enclosure before the formation of a
significant upper layer of heated combustion products. Due to the rapid
combustion of fuel spills on nonporous surfaces, the results of the study
may be applicable to many enclosures. 

Analytical predictions and empirical data concerning the spread of liquids
on ideal surfaces are available in the literature. The analytical predictions
are based on perfectly smooth, level, and nonporous surfaces. The
empirical data is derived from spills on very smooth level surfaces, such as
epoxy-coated concrete and metal.

The floor materials of interest to fire investigators, such as wood and vinyl
flooring, carpet, and unsealed concrete differ from the ideal surfaces
assumed in the analytical predictions. These flooring materials contain
joints and texture, and may be porous or semiporous. The spread of liquids
on these surfaces is expected to differ from those measured or predicted on
more ideal surfaces. This study investigates the spill and burning behavior
of liquid fuels on vinyl tile, wood parquet, and carpet flooring materials. In
order to provide inputs for fire modeling that can be especially useful in
fire condition prediction and fire scenario evaluation, the heat release rates
(HRRs) of the spill fires are measured. The liquid fuels used are gasoline
and kerosene, which are commonly encountered by fire investigators in
the field.

2. Analytical Spill Size Prediction

The literature[1] contains methods for predicting the spread of fluids on
smooth, level surfaces. The methods consist of fluid mechanics models
that assume a smooth, level surface and negligible evaporation. This
assumption will be an approximation in the case of wood and vinyl floors
due to surface texture, cracks, and the inability to produce a perfectly
smooth, level surface. The analysis is not applicable to carpeted surfaces
due to absorption into the carpet and pad.

Properties of the spreading fuel are important to the spreading process.
Characteristics such as fuel density, viscosity, surface tension, and the
interfacial tension between the liquid, the air, and the floor surface all
affect the spreading process.

When a liquid is spilled on a surface, a condition that is assumed to occur
instantaneously in the analytical predictions, the spreading process may be
divided into a series of three regimes, each of which is dominated by
different physical forces. The regimes occur in the following order:
gravity-inertia, gravity-viscous, and viscous-surface tension. In the
gravity-inertia regime, the forces of gravity are working to spread the fluid
and are opposed by the inertia of the fluid. In the gravity-viscous regime,
the viscous forces within the fluid oppose the gravity forces. Finally, in the
viscous-surface tension regime, the viscous forces within the fluid oppose
the surface tension forces. For the fuels and spill sizes investigated here,
the spill enters the viscous-surface tension regime very rapidly, on the
order of a few seconds from the time of the spill. The process for
calculating the spill thickness as a function of time differs depending on
the spill regime at the time of interest. Equation 1 is used to determine the
time at which the spill enters the viscous-surface tension regime. For t >
t[2], the spill is in the viscous-surface tension regime, and equation 2 may
be used to calculate the radius of the spill and derive the spill thickness.

The spill area was predicted as a function of time according to eq (1) and
eq (2), using the properties[2] listed in table 1. The results for two times of
interest are listed in table 2. 

The spreading of liquid fuels in industrial facilities has been studied for
fire hazard analyses[3]. In these experiments, spill thickness of 0.22 mm
resulted from unconfined spills of #2 fuel oil on epoxy-coated concrete
and steel surfaces. The study found that the unconfined spill thickness was
independent of the spill volume, a result that is applied in the current
study.

3. Spill Area

A series of eight spill area measurements were conducted using wood
parquet and vinyl flooring. Various quantities of fuel were poured onto
sections of flooring. The flooring sections consisted of a wood frame
constructed of 50 mm by 100 mm (2 in x 4 in) nominal wood lumber
covered with 16 mm (5/8 in) nominal plywood secured with nails. The
wood parquet flooring sections were constructed by applying adhesive to
the plywood surface and attaching the 300 mm by 300 mm (12 in by 12 in)
nominal wood parquet flooring tiles to the flooring sections. The wood
tiles are coated with a clear polyurethane finish at the factory and are
manufactured with tongue and groove connections along the tile perimeter.
The vinyl flooring sections were constructed by attaching a 6 mm (1/4 in)
nominal layer of dense fiberboard to the plywood surface with nails. Self-
sticking 300 mm by 300 mm (12 in by 12 in) nominal vinyl flooring tiles
were applied to the surface of the fiberboard. 

The liquid fuels were poured in the center of the flooring sections, with
approximate dimensions of 1.22 m by 1.22 m (4 ft x 4 ft), using the
apparatus shown in figure 1. The fuel was poured by rotating the
container, thereby discharging the fuel onto the center of the floor sample
from a height of 510 mm +/- 10 mm. (This estimated expanded uncertainty
is the result of a Type B evaluation with a coverage factor of 2.) The fuel
was allowed to spread and sit on the surface of the flooring for a duration
of approximately 60 s. In all cases, the fuel was observed to have stopped
spreading within the 60 s time period. The temperatures of the floor
samples and fuel were approximately equal to the ambient temperature,
which was approximately 24 degrees C (75 degrees F). 

Spill areas were measured using infrared imaging. The use of infrared
imaging was made possible by emissivity differences between the flooring
materials and the fuels, which were at approximately the same
temperature. This avoided the need to add dyes or other impurities to the
fuels to make them visible. The nominal thickness of the spill was
calculated from the spill area and spill quantity. Fuel evaporation and
soak-in were ignored due to the short duration of the measurements and
the use of nonporous surfaces. Figures 2 and 3 show the extent of the
spread of gasoline on wood parquet and vinyl tile floors. The fluid
traveling within the cracks of the flooring material can be clearly seen
along the periphery of the wood parquet floor spill. The presence of these
fuel dendrites was ignored in the calculation of spill thickness.

Spill thicknesses calculated using the analytical method are compared to
the experimental results in table 3. All of the uncertainties stated in this
report, unless otherwise noted, are expanded uncertainties derived from
Type A evaluations (statistical analysis of the data) with a coverage factor,
k, equal to 2. A coverage factor of 2 corresponds to a confidence interval
of approximately 95 %, assuming a normal distribution applies[4].

Due to the assumptions made in the analytical predictions, most
importantly the ideal surface, the spreading behavior of the spill is a
function of time. While the spreading in the experiments appeared to cease
in less than 60 s, the analytical predictions using eq (1) and eq (2) indicate
continual spread. Due to the differences in the analytically predicted and
empirical spill thicknesses for the floor coverings studied, the use of the
empirical data is recommended. The analytical prediction method is
useful, however, for understanding the spreading mechanisms of a fluid
spill. The predictions could be valuable for instances where the spill
method, fuels, or floor surfaces differ from those studied in this paper. To
this end, the analytical prediction method could be used to understand the
sensitivity of the spill thickness to variables such as fuel temperature, floor
temperature, fuel variations, etc.

Spill areas were also measured on carpeted floors. In this case, the edge of
the spill was indicated on the carpet with a black permanent marker, and
the dimensions of the elliptical spill measured with a meter stick. Two
types of carpet were used. Carpet "1" was composed of polyolefin, with
polypropylene backing. This carpet is designated as a home/office carpet,
with dense loop construction, and an approximate mass per unit area of
0.68 kg/m[2] (20 oz/yd[2]). Carpet "2" was a cut pile carpet composed of
nylon, with an approximate mass per unit area of 0.85 kg/m[2] (25
oz/yd[2]). Both carpet types were installed over polyurethane carpet
padding, with an approximate mass per unit area of 0.98 kg/m[2] (29
oz/yd[2]), and attached to a plywood sub-floor with tack strips along the
perimeter. Descriptions of the carpets and padding are summarized in table
4.

The carpet spills were conducted in an identical manner to those on the
nonporous surfaces, except for the area measurement method stated above,
and that a 2.44 m x 2.44 m section of flooring was used for all of the
spills. Since the carpet and pad absorb the spilled gasoline, the spill areas
for various quantities of fuel are listed in units of area instead of length
(thickness). The results are shown in table 5.

4. Spill Ignition Experiments

The full-scale fire experiments were conducted under an instrumented
exhaust hood in the laboratory. The laboratory space is temperature
controlled and for all experiments was approximately 20 degrees C (68
degrees F). The fuel was poured over the center of each 2.44 m by 2.44 m
(8.00 ft x 8.00 ft) nominal flooring section by rotating the vessel to the
horizontal. Upon completion of the pour, a soak-in time of approximately
60 s was observed to allow for the spread of the fuel over the surface.
During the soak-in time, an electric match consisting of a nickel-
chromium wire run through a book of paper matches, was placed in the
center of the spill. The spill was ignited at the end of the soak-in period.
The real-time heat release rate of the fire was calculated using oxygen
consumption calorimetry during the fire[5]. The nonporous flooring fires
were allowed to burn until they self-extinguished. The carpet fires were
extinguished at various times after ignition. Following extinguishment, the
burn pattern resulting from the fire was measured and photographed. The
experimental setup is shown in figures 1 and 4, while the gasoline fire
experimental matrix is shown in table 6. 

4.1 Nonporous Surfaces

As expected, the ignition and burning behaviors of gasoline and kerosene
differed. Gasoline (87 octane), a liquid with a closed cup flashpoint of -38
degrees C[6], ignited readily and consistently with flame spreading rapidly
over the entire surface of the spill (see fig. 5). In addition, vapors spread
past the confines of the spill during the soak-in time, resulting in
momentary burning over a larger area, which was not measured. Spill fires
approaching extinction are shown in figures 6 and 7. In both cases, fire can
be seen lingering in the cracks and seams present in the surfaces of the
floors.

Figures 8 through 11 show the typical patterns left by the gasoline fires.
Upon inspection of the floors after the burns, it was noted that the charring
was limited to the upper surface of the flooring and in the cracks of the
tiles. In the wood parquet flooring experiments, the plywood underlayment
was undamaged. In the vinyl flooring tests, the fiberboard underlayment
was undamaged, except for charring at the seams between the tiles. The
charring of the fiberboard can be seen in figures 12 and 13 where the tiles
pulled away from each other at the seams upon fire exposure. 

Kerosene, a liquid with a closed cup flashpoint of 55 degrees C[7], did not
ignite readily or consistently. The kerosene failed to ignite in most cases.
In some of the experiments, the kerosene did ignite in the locality of the
matches and slowly spread in the confines of cracks in the floor. This
behavior led to the pattern shown in figure 14. The kerosene fires self-
extinguished leaving large areas of the spill unburned. Given the limited
amount of burning from the kerosene, most of the experiments were
conducted with gasoline.

4.2 Carpeted Surfaces

The spill fires on carpeted flooring utilized gasoline (87 octane) as the
spilled fuel. As with the nonporous surfaces, the gasoline ignited readily
and consistently with flame spreading rapidly over the entire surface of the
spill. In addition, vapors spread past the confines of the spill during the
soak-in time, resulting in momentary burning over a larger area, which
was not measured. The two types of carpet differed qualitatively in the rate
of flame spread over the carpet surface. The flame spread rate of the cut
pile nylon carpet (carpet 2) was significantly less than that of the
polyolefin carpet (carpet 1) of loop construction. The flame spread rates
were not characterized quantitatively, but the fire area of the polyolefin
carpet experiments more than doubled in 90 s, as opposed to the nylon
carpet experiments where the burn area only increased slightly over the
same time period. This behavior is illustrated in figures 15 through 18. 

Close-up views of the burning carpet spills are shown in figures 19 and 20.

Post-fire, the burn pattern present on the carpeted floors exhibited a
"doughnut" type pattern, as can be seen in figures 21 through 24. The
presence of gasoline was limited to the inside doughnut, where significant
quantities of fuel were present. The melted carpet material inside the
doughnut protected the carpet padding from the effects of the fire (fig. 25).
The protected carpet pad was soaked with gasoline post-fire, and could be
reignited with an open flame. Several of the nylon carpeted fires were
allowed to burn for extended periods of time, approximately 1800 s (30
min), until the fire consisted of distributed areas of small individual flames
(fig. 26). The protected carpet padding inside the doughnut pattern was
soaked with gasoline after the extended burn time. After the fires were
extinguished, the carpet and padding could be removed, leaving the
doughnut pattern attached to the underlying plywood flooring. This is
shown in figure 27.

5. Analysis and Results

5.1 Spill and Burn Areas

The spill areas and burn areas for the nonporous floors are compared in
figures 28 and 29. The error bars on the graphs represent the expanded
uncertainty in the measurement of the spill area. The graphs illustrate good
agreement between the spill and burn areas for gasoline. The burn areas
from the gasoline spill fires on wood and vinyl floors are well represented
by a linear curve fit. The y-intercept is positive, suggesting the effects of
uncertainty, or that the burn area is slightly larger than the spill area. For
wood floors, the latter is illustrated by the comparison of the spill and burn
areas. In the case of vinyl, however, the spill and burn areas are essentially
the same. Note that for the wood and vinyl surfaces, the spill areas on the
graph are extrapolated from the 250 mL spills to the 500 mL and 1000 mL
spills. The basis for the extrapolation was previous work in the literature
[3] where unconfined spill thicknesses on nonporous surfaces were found
to be independent of spill volume. Points are shown at 500 mL and 1000
mL in order to illustrate the uncertainty in the extrapolation, derived from
the law of propagation of uncertainty and the uncertainty in the 250 mL
result.

The spill and initial burn areas for the carpet experiments, shown in figure
30, are well represented by a linear curve fit. The areas are greater for the
low pile looped polyolefin carpet as compared to the cut pile nylon carpet
as a consequence of the quantity of fuel the carpet is able to hold. In both
cases, the y-intercept is positive due to uncertainties and/or the pouring of
the fuel. Since the area of the pour stream is the same for all of the pours,
it would compose a greater percentage of the spill area at smaller spill
volumes. There is also a small amount of slop and splatter that occurs
when the fuel stream contacts the surface of the floor. As the spill volume
approaches zero, a minimum spill area would be expected, and the
extrapolation would cease to be valid. Note that the spill areas of the
porous surfaces are an order of magnitude smaller than those on the
nonporous surfaces studied.

5.2 Peak Heat Release Rate

The peak heat release rate versus spill volume relationships for the vinyl
and wood flooring are well represented by a linear curve fit, shown in
figure 31. Note that the y-intercept for the vinyl flooring is positive; it is
the result of uncertainty in the measurement, or possibly it illustrates the
contribution of the vinyl flooring material to the heat release rate. In
contrast to the vinyl-flooring plot, the linear fit for the wood flooring has a
negative y-intercept. This could be the result of uncertainty, or the
combined effects of the heat release rate contribution of the flooring and
the fluid lost into the cracks of the flooring material.

The peak heat release rate versus spill volume of the carpeted floors,
shown in figure 32, are both represented well by a linear fit, with the
polyolefin carpet spills having greater rates of heat release than the nylon
carpet spills, at the spill sizes examined. This result was expected given
the qualitative behavior observed during the experiments, where the
polyolefin burns exhibited a greater rate of flame spread than the nylon
carpet burns. In both cases, the fit has a positive y-intercept, due to the
uncertainty in the data, or to the heat release rate component of the carpet
and pad.

The peak heat release rates for the spill fires are compared to steady state
pool fire heat release rates in tables 7 and 8. The pool fire HRR values
were computed from correlations derived from large-scale pool fire
experiments[8,9]. The diameters used in the pool fire HRR correlations are
equivalent diameters, i.e., the areas of the pool fires are the same as the
areas of the spill fires. Peak heat release rates for the spills examined on
nonporous surfaces are approximately 1/4 to 1/8 of the heat release rates of
the pool fires. For the carpet spill fires, the peak heat release rates are
approximately equal to the steady state heat release rates of the equivalent
diameter pool fires. For the scenarios examined, the pool fire heat release
rates would not be good approximations for gasoline spills on nonporous
surfaces for modeling purposes. The pool fire heat release rates, however,
are good approximations for gasoline spill fire heat release rates on the
carpeted flooring surfaces examined.

The heat release rates of the fire experiments as a function of time are 
included in the graphs in appendix A.

5.3 Heat Release Rate Per Unit Area

The heat release rate per unit area (HRR/area) is nearly constant for the
vinyl flooring spill fires studied, and is shown in figure 33. The wood
flooring experiments, however, displayed an increase in the heat release
rate per unit area as the spill size increased. Given the overall behavior of
the HRR/area for the wood floor spills, and the HRR linear curve fit which
has a negative y-intercept, some of the fuel may have been lost into the
cracks of the parquet surface. Given the construction of the flooring, it
would be expected that more fuel would be lost into the parquet than into
the vinyl due to the greater crack length per unit area of the parquet
flooring.

The HRR/area for the spills on carpet are shown in figure 34. The spills on
polyolefin carpet have a nearly constant HRR/area over the spill size range
studied. For the nylon carpet, a linear fit is not a good representation for
the HRR/area data. As a comparison, the pool fire HRR/area is nearly
constant over the range of equivalent pool fire diameters examined [8].
The resulting pool fires in this range would be in the turbulent flow
regime, where radiative feedback effects and turbulent flow effects are
important. The reason for the larger HRR/area value resulting from the
500 mL nylon carpet burns should be studied further.

6. Conclusions

Based on a limited number of experiments, the conclusions of this study
can be summarized by the following:

1. The spill area can be predicted from the fuel quantity. The empirically
derived spill thickness can be used to predict the size of spills.

2. In all but one scenario, the nonporous flooring gasoline burn areas were
found to be the same as the spill areas within the experimental uncertainty. 

3. Initial carpet burn areas were found to be the same as the carpet spill
areas, within the experimental uncertainty.

4. The quantity of gasoline spilled could be determined from the burn
pattern area on nonporous flooring.

5. Significant quantities of spilled fuel were present after extinguishment
and extinction of the carpeted fires. The melted carpet inside the doughnut
protected the unburned liquid.

6. Peak heat release rates for the spills examined on nonporous surfaces
are approximately 1/4 to 1/8 of the heat release rates of equivalent
diameter pool fires. For the carpet spill fires, the peak heat release rates are
approximately equal to the steady state heat release rates of the equivalent
diameter pool fires.

7. Pool fire heat release rates may be useful for fire modeling and fire
scenario evaluation for spill fires on carpeted floors. Fire modeling and
fire scenario evaluation for spill fires on nonporous floors should not be
conducted using the heat release rates derived from pool fires.

This report provides a means for fire investigators to predict the quantity
of spilled gasoline necessary to produce a fire pattern of a particular size
on various types of commonly used flooring materials. It also includes
measurements of spill fire heat release rates that provide fire investigators
and other fire professionals with previously unavailable data for fire
modeling and fire scenario evaluation.

7. REFERENCES

1. P.P.K. Raj and A.S. Kalelkar, Assessment Models in Support of the
Hazard Assessment Handbook. U.S. Coast Guard Report AD-776 617,
U.S. Coast Guard Headquarters, Washington, DC (1974).

2. J.W. Murdock, "Mechanics of Fluids." Marks' Standard Handbook for
Mechanical Engineers. Tenth Edition, E.A. Avallone and T. Baumeister
III, eds., McGraw-Hill, New York, NY (1996), pp. 3-31 to 3-33. 

3. A.T. Modak, "Ignitability of High-Fire-Point Liquid Spills." EPRI
Report NP-1731, Electric Power Research Institute, Palo Alto, CA (1981).

4. B.N. Taylor and C.E. Kuyatt, "Guidelines for Evaluating and
Expressing the Uncertainty of NIST Measurement Results." NIST
Technical Note 1297, 1994 Edition, National Institute of Standards and
Technology, Gaithersburg, MD 20899.

5. V. Babrauskas, R.L. Lawson, W.D. Walton, and W.H. Twilley,
"Upholstered Furniture Heat Release Rates Measured With a Furniture
Calorimeter." NBSIR 82-2604, National Bureau of Standards, December
1982.

6. D. Drysdale, "Ignition: The Initiation of Flaming Combustion." An
Introduction to Fire Dynamics. John Wiley & Sons Ltd., Reprinted
September 1986, p. 197.

7. A.M. Kanury, "Ignition of Liquid Fuels." SFPE Handbook of Fire
Protection Engineering, Second Edition, P.J. DiNenno et al. eds., Society
of Fire Protection Engineers, Boston (1995), pp. 2-163.

8. K.S. Mudan and P.A. Croce, "Fire Hazard Calculations for Large Open 
Hydrocarbon Fires." SFPE Handbook of Fire Protection Engineering,
Second Edition, P.J. DiNenno et. al. eds., Society of Fire Protection
Engineers, Boston (1995) pp. 3-199.

9. A. Tewarson, "Generation of Heat and Chemical Compounds in Fires."
SFPE Handbook of Fire Protection Engineering, Second Edition, P.J.
DiNenno et al. eds., Society of Fire Protection Engineers (1995), pp. 3-78.