In the design of gas turbine combustors, efforts are engineered toward reducing the combustion pollutant emission levels. The pollutant emissions can be reduced by premixing the fuel and the air prior to ignition. However, the main challenges encountered with premixing are flame flashback and blowout, thus, the preference of diffusion flames. In this study, flame behavior, flow patterns, and thermochemical fields of backward-inclined diffusion jet flames in crossflow at low jet-to-crossflow momentum flux ratio of smaller than 0.04 were studied in a wind tunnel. The backward-inclination angle was varied within 0–50 deg. The flames presented three characteristic modes: crossflow dominated flame (low backward inclination angle) denoted by a large down-washed recirculation flame, transitional flame (mediate backward inclination angle) identified by a recirculation flame and a tail flame, and jet dominated flame (high backward inclination angle) characterized by a blue flame base, a yellow tail flame, and the absence of a recirculation flame. Short flames are detected in the regime of the crossflow dominated flames—an indication of improved fuel–air mixing. The findings suggest that for low exhaust emissions which are vigorously pursued in the aviation and thermal power plant industries, especially during low-load operations, the jet dominated flames are the preferable flames as they generate low unburned hydrocarbon, carbon monoxide, and nitric oxide emissions compared to the other flames.
Issue Section:
Gas Turbines: Combustion, Fuels, and Emissions
References
1.
Escudier
, M. P.
, 1971
, “Aerodynamics of a Burning Turbulent Gas Jet in a Crossflow
,” Combust. Sci. Technol.
, 4
(1
), pp. 293
–301
.2.
Karagozian
, A. R.
, 1986
, “The Flame Structure and Vorticity Generated by a Chemically Reactingtransverse Jet
,” AIAA J.
, 24
(9
), pp. 1502
–1507
.3.
Kolla
, H.
, Grout
, R. W.
, Gruber
, A.
, and Chen
, J. H.
, 2012
, “Mechanisms of Flame Stabilization and Blowout in a Reacting Turbulent Hydrogen Jet in Cross-Flow
,” Combust. Flame
, 159
(8
), pp. 2755
–2766
.4.
Wagner
, J. A.
, Grib
, S. W.
, Renfro
, M. W.
, and Cetegen
, B. M.
, 2015
, “Flowfield Measurements and Flame Stabilization of a Premixed Reacting Jet in Vitiated Crossflow
,” Combust. Flame
, 162
(10
), pp. 3711
–3727
.5.
Steinberg
, A. M.
, Sadanandan
, R.
, Dem
, C.
, Kutne
, P.
, and Meier
, W.
, 2013
, “Structure and Stabilization of Hydrogen Jet Flames in Cross-Flows
,” Proc. Combust Inst.
, 34
(1
), pp. 1499
–1507
.6.
Ben-Yakar
, A.
, and Hanson
, R. K.
, 1998
, “Experimental Investigation of Flame-Holding Capability of Hydrogen Transverse Jet in Supersonic Cross-Flow
,” Symp. (Int.) Combust.
, 27
(2
), pp. 2173
–2180
.7.
Hasselbrink
, E. F.
, and Mungal
, M. G.
, 2001
, “Transverse Jets and Jet Flames Part 1 Scaling Laws for Strong Transverse Jets
,” J. Fluid Mech.
, 443
, pp. 1
–25
.8.
Grout
, R. W.
, Gruber
, A.
, Yoo
, C. S.
, and Chen
, J. H.
, 2011
, “Direct Numerical Simulation of Flame Stabilization Downstream of a Transverse Fuel Jet in Cross-Flow
,” Proc. Combust Inst.
, 33
(1
), pp. 1629
–1637
.9.
Brzustowski
, T. A.
, Gollahalli
, S. R.
, and Sullivan
, H. F.
, 1975
, “The Turbulent Hydrogen Diffusion Flame in a Cross-Wind
,” Combust. Sci. Technol.
, 11
(1–2
), pp. 29
–33
.10.
Gollahalli
, S. R.
, Brzustowski
, T. A.
, and Sullivan
, H. F.
, 1975
, “Characteristics of a Turbulent Propane Diffusion Flame in a Cross-Wind
,” Trans. Can. Mech. Eng.
, 3
(4
), pp. 205
–214
.11.
Brzustowski
, T. A.
, 1976
, “Flaring in the Energy Industry
,” Prog. Energy Combust. Sci.
, 2
(3
), pp. 129
–141
.12.
Botros
, P. E.
, and Brzustowski
, T. A.
, 1979
, “An Experimental and Theoretical Study of the Turbulent Diffusion Flame in Cross-Flow
,” Symp. (Int.) Combust.
, 17
(1
), pp. 389
–398
.13.
Kalghatgi
, G. T.
, 1981
, “Blow-Out Stability of Gaseous Jet Diffusion Flames—Part II: Effect of Cross Wind
,” Combust. Sci. Technol.
, 26
(5–6
), pp. 241
–244
.14.
Birch
, A. D.
, Brown
, D. R.
, Fairweather
, M.
, and Hargrave
, G. K.
, 1989
, “An Experimental Study of a Turbulent Natural Gas Jet in a Cross-Flow
,” Combust. Sci. Technol.
, 66
(4–6
), pp. 217
–232
.15.
Askari
, A.
, Bullman
, S. J.
, Fairweather
, M.
, and Swaffield
, F.
, 1990
, “The Concentration Field of a Turbulent Jet in a Cross-Wind
,” Combust. Sci. Technol.
, 73
(1–3
), pp. 463
–478
.16.
Ellzey
, J. L.
, Berbe
, J. G.
, Tay
, E. Z. F.
, and Foster
, D. E.
, 1990
, “Total Soot Yield From a Propane Diffusion Flame in Cross-Flow
,” Combust. Sci. Technol.
, 71
(1–3
), pp. 41
–52
.17.
Fairweather
, M.
, Jones
, W. P.
, Lindstedt
, R. P.
, and Marquis
, A. J.
, 1991
, “Predictions of a Turbulent Reacting Jet in a Cross-Flow
,” Combust. Flame
, 84
(3–4
), pp. 361
–375
.18.
Gollahalli
, S. R.
, and Nanjundappa
, B.
, 1995
, “Burner Wake Stabilized Gas Jet Flames in Cross-Flow
,” Combust. Sci. Technol.
, 109
(1–6
), pp. 327
–346
.19.
Bourguignon
, E.
, Johnson
, M. R.
, and Kostiuk
, L. W.
, 1999
, “The Use of a Closed-Loop Wind Tunnel for Measuring the Combustion Efficiency of Flames in a Cross Flow
,” Combust. Flame
, 119
(3
), pp. 319
–334
.20.
Bandaru
, R. V.
, and Turns
, S. R.
, 2000
, “Turbulent Jet Flames in a Crossflow: Effects of Some Jet, Crossflow, and Pilot-Flame Parameters on Emissions
,” Combust. Flame
, 121
(1–2
), pp. 137
–151
.21.
Johnson
, M. R.
, and Kostiuk
, L. W.
, 2000
, “Efficiencies of Low-Momentum Jet Diffusion Flames in Crosswinds
,” Combust. Flame
, 123
(1–2
), pp. 189
–200
.22.
Johnson
, M. R.
, Wilson
, D. J.
, and Kostiuk
, L. W.
, 2001
, “A Fuel Stripping Mechanism for Wake-Stabilized Jet Diffusion Flames in Crossflow
,” Combust. Sci. Technol.
, 169
(1
), pp. 155
–174
.23.
Majeski
, A. J.
, Wilson
, D. J.
, and Kostiuk
, L. W.
, 2004
, “Predicting the Length of Low-Momentum Jet Diffusion Flames in Crossflow
,” Combust. Sci. Technol.
, 176
(12
), pp. 2001
–2025
.24.
Sullivan
, R.
, Wilde
, B.
, Noble
, D. R.
, Seitzman
, J. M.
, and Lieuwen
, T. C.
, 2014
, “Time-Averaged Characteristics of a Reacting Fuel Jet in Vitiated Cross-Flow
,” Combust. Flame
, 161
(7
), pp. 1792
–1803
.25.
Huang
, R. F.
, Kimilu
, R. K.
, and Hsu
, C. M.
, 2016
, “Effects of Jet Pulsation Intensity on a Wake-Stabilized Non-Premixed Jet Flame in Crossflow
,” Exp. Therm. Fluid Sci.
, 78
, pp. 153
–166
.26.
Hasselbrink
, E. F.
, and Mungal
, M. G.
, 1998
, “Observations on the Stabilization Region of Lifted Non-Premixed Methane Transverse Jet Flames
,” Symp. (Int.) Combust.
, 27
(1
), pp. 1167
–1173
.27.
Gollahalli
, S. R.
, and Pardiwalla
, D.
, 2002
, “Comparison of the Flame Characteristics of Turbulent Circular and Elliptic Jets in a Crossflow
,” ASME J. Energy Resour. Technol.
, 124
(3
), pp. 197
–203
.28.
Kostiuk
, L. W.
, Mejeski
, A. J.
, Poudenx
, P.
, Johnson
, M. R.
, and Wilson
, D. J.
, 2000
, “Scaling of Wake-Stabilized Jet Diffusion Flames in a Transverse Air Stream
,” Proc. Combust Inst.
, 28
(1
), pp. 553
–559
.29.
Huang
, R. F.
, and Chang
, J. M.
, 1994
, “The Stability and Visualized Flame and Flow Structures of a Combusting Jet in Cross Flow
,” Combust. Flame
, 98
(3
), pp. 267
–278
.30.
Kalghatgi
, G. T.
, 1982
, “Blow-Out Stability of Gaseous Jet Diffusion Flames—Part III: Effect of Burner Orientation to Wind Direction
,” Combust. Sci. Technol.
, 28
(5–6
), pp. 241
–245
.31.
Han
, D.
, and Mungal
, M. G.
, 2003
, “Simultaneous Measurements of Velocity and CH Distribution. Part II: Deflected Jet Flames
,” Combust. Flame
, 133
(1–2
), pp. 1
–17
.32.
Luo
, M. C.
, 1997
, “Effects of Radiation on Temperature Measurement in a Fire Environment
,” J. Fire Sci.
, 15
(6
), pp. 443
–461
.http://journals.sagepub.com/doi/10.1177/073490419701500602 33.
Huang
, R. F.
, and Wang
, S. M.
, 1999
, “Characteristic Flow Modes of Wake-Stabilized Jet Flames in a Transverse Air Stream
,” Combust. Flame
, 117
(1–2
), pp. 59
–77
.34.
Huang
, R. F.
, and Yang
, M. J.
, 1996
, “Thermal and Concentration Fields of Burner-Attached Jet Flames in Cross Flow
,” Combust. Flame
, 105
(1–2
), pp. 211
–224
.35.
Khouygani
, M. G.
, Huang
, R. F.
, and Hsu
, C. M.
, 2015
, “Flow Characteristics in Median Plane of a Backward-Inclined Elevated Transverse Jet
,” Exp. Therm. Fluid Sci.
, 62
, pp. 164
–174
.36.
Han
, D. H.
, Orozco
, V.
, and Mungal
, M. G.
, 2000
, “Gross-Entrainment Behavior of Turbulent Jets Injected Obliquely Into a Uniform Crossflow
,” AIAA J.
, 38
(9
), pp. 1643
–1649
.37.
Kimilu
, R. K.
, Huang
, R. F.
, and Hsu
, C. M.
, 2016
, “Non-Premixed Burner-Attached Jet Flames in Crossflow Pulsed at Resonance Frequency
,” J. Propul. Power
, 33
(6
), pp. 1332
–1350
.38.
Liu
, Y.
, Sun
, X.
, Sethi
, V.
, Nalianda
, D.
, Li
, Y.-G.
, and Wang
, L.
, 2017
, “Review of Modern Low Emissions Combustion Technologies for Aero Gas Turbine Engines
,” Prog. Aerosp. Sci.
, 94
, pp. 12
–45
.39.
Savas
, O.
, Huang
, R. F.
, and Gollahalli
, S. R.
, 1997
, “Structure of the Flow Field of a Nonpremixed Gas Jet Flame in Cross-Flow
,” ASME J. Energy Resour. Technol.
, 119
(2
), pp. 137
–144
.Copyright © 2019 by ASME
You do not currently have access to this content.
