Anytime flammable gas mixtures are handled, there is a risk of combustion. This is particularly true in many industrial applications where space is limited and equipment is located near sources of ignition. Unfortunately, there is a lack of understanding of combustion phenomena within process equipment such as mufflers, rotating blowout preventers, liquid traps, and dry gas seal assemblies. These vessels have small internal volumes, complex internal geometries, and are connected using small diameter piping. This paper discusses the results of a parametric study which was carried out to establish the nature of combustion within such vessels and tubing. The test vessel had an internal volume of 7 in3 (115 ml) and the tubing had a nominal diameter of 0.5 in (1.27 mm). Flowing, turbulent, pre-mixed natural gas/air mixtures were used. The study did not attempt to increase turbulence using devices such as mesh screens or attempt to stabilize the flame. The results from a representative sample of 76 tests, from the 5,000+ tests that have been completed, are discussed herein. Typical pressure and temperature responses are presented and analyzed. It is demonstrated that flames can be remotely detected using only high speed pressure data. Turbulent flames were formed whose velocity was found to be linearly dependant on Reynolds number.

Issue Section:
Technical Papers
Keywords:
gas mixtures, flames, turbulence, pipe flow, combustion
Topics:
Combustion, Flames, Natural gas, Pressure, Temperature, Tubing, Turbulence, Exhaust systems, Flow (Dynamics)
1.
Borman, G. L., and Ragland, K. W., 1998, “Combustion Engineering,” McGraw-Hill.
2.
Lin˜a´n, A., and Williams, F. A., 1997, “Fundamental Aspects of Combustion,” Oxford Engineering Sciences Series 34, Oxford University Press.
3.
Sokolik, A. S., 1963, “Self-Ignition Flame and Detonation in Gases,” Israel Program for Scientific Translations.
4.
Stull
,
D. R.
,
1977
, “
Fundamentals of Fire and Explosion
,”
American Institute of Chemical Engineers
, AIChE Monograph Series
73
,
No. 10
No. 10
.
5.
Williams, F. A., 1985, “Combustion Theory: The Fundamental Theory of Chemically Reacting Flow Systems,” Addison-Wesley Publishing Company, Inc.
6.
Perkins
,
T. K.
, and
Euchner
,
J. A.
,
1987
, “
Safe Purging of Natural Gas Pipelines
,” Society of Petroleum Engineers, SPE Paper 16184 SPHERE 1988, pp. 663.
7.
Bollinger, L. M., and Williams, D. T., 1948, “Effect of Reynolds Number in the Turbulent-Flow Range on Flame Speeds of Bunsen-Burner Flame,” NACA TM-1707, Lewis Flight Propulsion Laboratory, National Advisory Committee for Aeronautics.
8.
Olson, W. T., 1958, “Basic Considerations in the Combustion of Hydrocarbon Fuels With Air,” NACAR 1300, Lewis Flight Propulsion Laboratory, National Advisory Committee for Aeronautics.
9.
Shy, S. S., Lin, W. J., and Wei, J. C., 1999, “Turbulent Burning Velocities of CH4-Air Mixtures in a New Turbulent Flow System,” 17th International Colloquium on the Dynamics of Explosions and Reactive Systems, Heidelberg, Germany.
10.
Sato, K. S., Sakai, Y., and Chiga, M., 1996, “Flame Propagation Along 90 Bend in an Open Duct,” 26th Symposium (International) on Combustion, The Combustion Institute, pp. 931–937.
11.
Sobiesiak, A., and McAlary, G., 1999, “Flame Propagation in Straight Channel With 90 Curved Section,” 17th International Colloquium on the Dynamics of Explosions and Reactive Systems, Heidelberg, Germany.
12.
Zamashchikov, V. V., 1997, “Experimental Investigation of Gas Combustion Regimes in Narrow Tubes,” Combustion and Flame, The Combustion Institute, 108, pp. 357–359.
13.
Dunn-Rankin, D., and McCann, M. A., 2000, “Overpressures From Nondetonating, Baffle-Accelerated Turbulent Flames in Tubes,” Combustion and Flame, The Combustion Institute, 120, pp. 504–514.
14.
Leason
,
D. B.
,
1951
, “
Turbulence and Flame Propagation in Premixed Gases
,”
Fuel
,
10
, pp.
233
239
, October.
15.
Lindstedt, R. P., and Michels, H. J., 1989, “Deflagration to Detonation Transitions and Strong Deflagrations in Alkane and Alkene Air Mixtures,” Combustion and Flame, 76, pp. 169–181.
16.
Catlin, C. A., Fairweather, M., and Ibrahim, S. S., 1995, “Predictions of Turbulent, Premixed Flame Propagation in Explosion Tubes,” Combustion and Flame, The Combustion Institute, 102, pp. 115–128.
17.
Johnson, D. M., and Vasey, M. W., 1996, “The Prevention and Mitigation of Gas Explosions,” International Conference on Health, Safety & Environment, Society of Petroleum Engineers, SPE Paper 35810, New Orleans, Louisiana, 9–12 June.
18.
Bruneaux, G., Akselvoll, K., Poinsot, T., and Ferziger, J. H., 1996, “Flame-Wall Interaction Simulation in a Turbulent Channel Flow,” Combustion and Flame, The Combustion Institute, 107, pp. 27–44.
19.
Bray
,
K. N. C.
,
1990
, “
Studies of the Turbulent Burning Velocity
,”
Proc. R. Soc. London
,
431
, pp.
315
335
.
20.
Potter, A. E., Jr., and Berlad, A. L., 1954, “A Thermal Equation for Flame Quenching,” NACAR 1264, Lewis Flight Propulsion Laboratory, National Advisory Committee for Aeronautics.
21.
Swett, C. C., Jr., 1956, “Spark Ignition of Flowing Gases,” NACA R 1287, Lewis Flight Propulsion Laboratory, National Advisory Committee for Aeronautics.
22.
Lieuwen, T., and Rajaram, R., “Acoustic Radiation From Premixed Flames Subjected to Convected Flow Disturbances,” 40th AIAA Aerospace Sciences Meeting and Exhibit, Paper AIAA-02-0480, Reno, Nevada, 14–17 January, 2002.
23.
Hurle, I. R., Price, R. B., Sugden, T. M., Thomas, A., and Thomas, F. R. S., 1968, “Sound Emission From Open Turbulent Premixed Flames,” Proceedings of the Royal Society A., 303, pp. 409–427.
24.
Rajaram, R., and Lieuwen, T., “Parametric Studies of Acoustic Radiation From Premixed Flames,” 38th AIAA/AME/SAE/ASEE Joint Propulsion Conference and Exhibit, Paper AIAA-2002-3864, Indianapolis, Indiana, 7–10 July, 2002.
25.
Glassman, I., 1996, Combustion, Academic Press.
26.
Crane eds., 1984, “Flow of Fluids Through Valves, Fittings, and Pipe,” Technical Paper 410M, Crane Canada Inc.: Valve & Industrial Div., Montre´al.
Copyright © 2003
 by ASME
You do not currently have access to this content.