Simulations and exhaust measurements of temperature and pollutants in a syngas-fired model trapped vortex combustor for stationary power generation applications are reported. Numerical simulations employing Reynolds-averaged Navier–Stokes (RANS) and large eddy simulations (LES) with presumed probability distribution function (PPDF) model were also carried out. Mixture fraction profiles in the trapped vortex combustor (TVC) cavity for nonreacting conditions show that LES simulations are able to capture the mean mixing field better than the RANS-based approach. This is attributed to the prediction of the jet decay rate and is reflected on the mean velocity magnitude fields, which reinforce this observation at different sections in the cavity. Both RANS and LES simulations show close agreement with the experimentally measured OH concentration; however, the RANS approach does not perform satisfactorily in capturing the trend of velocity magnitude. LES simulations satisfactorily capture the trend observed in exhaust measurements which is primarily attributed to the flame stabilization mechanism. In the exhaust measurements, mixing enhancement struts were employed, and their effect was evaluated. The exhaust temperature pattern factor was found to be poor for baseline cases, but improved with the introduction of struts. NO emissions were steadily below 3 ppm across various flow conditions, whereas CO emissions tended to increase with increasing momentum flux ratios (MFRs) and mainstream fuel addition. Combustion efficiencies ∼96% were observed for all conditions. The performance characteristics were found to be favorable at higher MFRs with low pattern factors and high combustion efficiencies.

References

1.
Singhal
,
A.
, and
Ravikrishna
,
R. V.
,
2011
, “
Single Cavity Trapped Vortex Combustion Dynamics—Part 1: Experiments
,”
Int. J. Spray Combust. Dyn.
,
3
(
1
), pp.
23
44
.
2.
Singhal
,
A.
, and
Ravikrishna
,
R. V.
,
2011
, “
Single Cavity Trapped Vortex Combustion Dynamics—Part-2: Simulations
,”
Int. J. Spray Combust. Dyn.
,
3
(
1
), pp.
45
52
.
3.
Agarwal
,
K. K.
, and
Ravikrishna
,
R. V.
,
2011
, “
Experimental and Numerical Studies in a Compact Trapped Vortex Combustor: Stability Assessment and Augmentation
,”
Combust. Sci. Technol.
,
183
(
12
), pp.
1308
1327
.
4.
Agarwal
,
K. K.
, and
Ravikrishna
,
R. V.
,
2012
, “
Validation of a Modified Eddy Dissipation Concept Model for Stationary and Non-Stationary Diffusion Flames
,”
Combust. Sci. Technol.
,
184
(
2
), pp.
151
164
.
5.
Agarwal
,
K. K.
, and
Ravikrishna
,
R. V.
,
2013
, “
Mixing Enhancement in a Compact Trapped Vortex Combustor
,”
Combust. Sci. Technol.
,
185
(
3
), pp.
363
378
.
6.
Krishna
,
S.
, and
Ravikrishna
,
R. V.
,
2015
, “
Optical Diagnostics of Fuel-Air Mixing and Vortex Formation in a Cavity Combustor
,”
Exp. Therm. Fluid Sci.
,
61
, pp.
163
176
.
7.
Krishna
,
S.
, and
Ravikrishna
,
R. V.
,
2015
, “
Quantitative OH PLIF Diagnostics of Syngas and Methane Combustion in a Cavity Combustor
,”
Combust. Sci. Technol.
,
187
(
11
), pp.
1661
1682
.
8.
Jin
,
Y.
,
Li
,
Y.
,
Xiaomin
,
H.
,
Zhang
,
J.
,
Jiang
,
B.
,
Wu
,
Z.
, and
Song
,
Y.
,
2014
, “
Experimental Investigations on Flow Field and Combustion Characteristics of a Model Trapped Vortex Combustor
,”
Appl. Energy
,
134
, pp.
257
269
.
9.
Nemitallah
,
M. A.
, and
Mohamed
,
A. H.
,
2013
, “
Experimental and Numerical Investigations of an Atmospheric Diffusion Oxy-Combustion Flame in a Gas Turbine Model Combustor
,”
Appl. Energy
,
111
, pp.
401
415
.
10.
Zeinivand
,
H.
, and
Bazdidi-Tehrani
,
F.
,
2012
, “
Influence of Stabilizer Jets on Combustion Characteristics and NOx Emission in a Jet-Stabilized Combustor
,”
Appl. Energy
,
92
, pp.
348
360
.
11.
Zhang
,
R. C.
,
Fan
,
W. J.
,
Shi
,
Q.
, and
Tan
,
W. L.
,
2014
, “
Combustion and Emissions Characteristics of Dual-Channel Double-Vortex Combustion for Gas Turbine Engines
,”
Appl. Energy
,
130
, pp.
314
325
.
12.
Arghode
,
V. K.
, and
Gupta
,
A. K.
,
2013
, “
Role of Thermal Intensity on Operational Characteristics of Ultra-Low Emission Colourless Distributed Combustion
,”
Appl. Energy
,
111
, pp.
930
956
.
13.
Li
,
J.
,
Zhao
,
Z.
,
Kazakov
,
A.
,
Chaos
,
M.
,
Dryer
,
F. L.
, and
Scire
,
J. J.
, Jr.
,
2009
, “
A Comprehensive Kinetic Mechanism for CO, CH2O, and CH3OH Combustion
,”
Int. J. Chem. Kinet.
,
39
(
3
), pp.
109
136
.
14.
Cuoci
,
A.
,
Frassoldati
,
A.
,
Ferraris
,
G. B.
,
Faravelli
,
T.
, and
Ranzi
,
E.
,
2007
, “
The Ignition, Combustion and Flame Structure of Carbon Monoxide/Hydrogen Mixtures—Note 2: Fluid Dynamics and Kinetic Aspects of Syngas Combustion
,”
Int. J. Hydrogen Energy
,
32
(
15
), pp.
3486
3500
.
15.
Krishna
,
S.
,
Pramanik
,
S.
, and
Ravikrishna
,
R. V.
,
2013
, “
Numerical Modelling of a Turbulent Non-Premixed CO/H2/N2 Flame
,”
23rd National Conference on IC Engines and Combustion
(NCICEC), Surat, India, Dec. 13–16.
16.
Kemenov
,
K. A.
,
Wang
,
H.
, and
Pope
,
S. B.
,
2009
, “
Grid Resolution Effects on LES of a Piloted Methane-Air Flame
,”
Sixth U.S. National Combustion Meeting
, Ann Arbor, MI, May 17–20, pp.
146
159
.https://tcg.mae.cornell.edu/pubs/Kemenov_WP_09.pdf
17.
Boudier
,
G.
,
Gicquel
,
L. Y. M.
,
Poinsot
,
T.
,
Bissieres
,
D.
, and
Berat
,
C.
,
2009
, “
Effect of Mesh Resolution on Large Eddy Simulation of Reacting Flows in Complex Geometry Combustors
,”
Combust. Flame
,
155
(
1–2
), pp.
196
214
.
18.
Barlow
,
R. S.
,
Fiechtner
,
G. J.
,
Carter
,
C. D.
, and
Chen
,
J.-Y.
,
2000
, “
Experiments of the Scalar Structure of Turbulent CO/H2/N2 Jet Flames
,”
Combust. Flame
,
120
(
4
), pp.
549
569
.
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