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TECHNICAL PAPERS: Gas Turbines: Coal, Biomass, and Alternative Fuels

A Study of Combustion Characteristics of Gasified Coal Fuel

[+] Author and Article Information
T. Hasegawa, M. Sato

Central Research Institute of Electric Power Industry, Yokosuka, Kanagawa, Japan

T. Nakata

Department of Aeronautics and Space Engineering, Tohoku University, Sendai, Miyagi, Japan

J. Eng. Gas Turbines Power 123(1), 22-32 (May 15, 2000) (11 pages) doi:10.1115/1.1287586 History: Received March 09, 1999; Revised May 15, 2000
Copyright © 2001 by ASME
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References

Mizutani,  H., 1995, “Future View of Combined Cycle,” The Thermal and Nuclear Power, Thermal and Nuclear Power Eng. Soc., 46, No. 469, pp. 1198–1222.
See, for example, Regenbogen, R. W., 1995, Proc. the 12th Annual Int. Pittsburgh Coal Conf., p. 78.
Ishizuka, S., and Tsuji, H., 1981, “An Experimental Study of Effect of Inert Gases on Extinction of Laminar Diffusion Flames,” Proc. 18th Symp. (Int.) on Combust. The Combust. Inst., Pittsburgh, PA, p. 695.
Morgan, G. H., and Kane, W. R., 1962, Proc. 9th Symp. (Int.) on Combust., The Combust. Inst., Pittsburgh, PA, p. 313.
Coward, H. F., and Jones, G. E., 1971, “Flammability Characteristics of Combustion Gases and Vapors,” Bulletin 627, Bureau of Mines.
Ishibasi, Y., and Kuroda, R., 1978, Proc. the 6th Annual Conf. Gas Turbine Soc. Jpn., p. 7.
Folsom,  B. A., Courtney,  C. W., and Heap,  M. P., 1980, “The Effects of LBG Composition and Combustor Characteristics on Fuel NOx Formation,” ASME J. Eng. Power, 102, p. 459.
Drake, M. C., Pitz, R. W., Correa, S. M., and Lapp, M., 1984, “Nitric Oxide Formation from Thermal and Fuel-Bound Nitrogen Sources in a Turbulent Nonpremixed Syngas Flame,” Proc. 20th Symp. (Int.) Combust., The Combust. Inst., Pittsburgh, PA, pp. 1983–1990.
Döbbeling, K., Eroglu, A., Winkler, D., Sattelmayer, T., and Keppel, W., 1996, “Low NOx Premixed Combustion of MBtu Fuels in a Research Burner,” ASME Paper 96-GT-126.
Pillsbury,  P. W., Cleary,  E. N. G., Singh,  P. P., and Chamberlin,  R. M., 1976, “Emission Results form Coal Gas Burning in Gas Turbine Combustors,” ASME J. Eng. Power, 98, p. 88.
Clark,  W. D., Folsom,  B. A., Seeker,  W. R., and Courtney,  C. W., 1982, “Bench Scale Testing of Low-NOx LBG Combustors,” ASME J. Eng. Power, 104, p. 120.
Battista, R. A., and Farrell, R. A., 1979, “Development of an Industrial Gas Turbine Combustor Burning a Variety of Coal-Derived Low Btu Fuels and Distillate,” ASME Paper 79-GT-172.
Beebe, K. W., et al., 1982. DOE/NASA/13111-11, NASA TM, 82985.
Döbbeling, K., Knöpfel, H. P., Polifke, W., Winkler, D., Steinbach, C., and Sattelmayer, T., 1994, “Low NOx Premixed Combustion of MBtu Fuels Using the ABB Double Cone Burner (EV Burner),” ASME Paper 94-GT-394.
Cook, C. S., Corman, J. C., and Todd, D. M., 1994, “System Evaluation and LBtu Fuel Combustion Studies for IGCC Power Generation,” ASME Paper 94-GT-366.
Sato,  M., Nakata,  T., and Yamauchi,  K., 1990, “NOx Emission Characteristics of Coal-Derived Low Btu Gas Fuel,” J. Fuel Soc. Jpn., 69, No. 10, pp. 952–959.
Nakata,  T., and Sato,  M., 1991, “Reaction Analysis of Coal Gaseous Fuel in a Gas Turbine Combustor,” J. Jpn. Inst. Energy, 71, No. 1, pp. 84–41.
Yamauchi,  K., Sato,  M., and Nakata,  T., 1991, “The Effect of CH4 Contained in Coal Gas Fuel on NOx Formation,” Trans. Jpn. Soc. Mech. Eng., Ser. B, 57, No. 535, pp. 811–818.
Nakata,  T., Sato,  M., and Hasegawa,  T., 1998, “Reaction of Fuel NOx Formation for Gas Turbine Conditions,” Trans. ASME: J. Eng. Gas Turbines Power, 120, No. 3, pp. 474–480.
Sato,  M., Nakata,  T., Yoshine,  T., and Yamada,  M., 1990, “Development of a 1300 °C-Class Gas Turbine Combustor Burning Coal-Derived Low-Btu Gaseous Fuels,” Trans. Jpn. Soc. Mech. Eng., Ser. B, 56, No. 530, pp. 3147–3154.
Sato,  M., Ninomiya,  T., Abe,  T., Yoshine,  T., and Hasegawa,  H., 1990, “Development of a 1300 °C-Class Gas Turbine Combustor Burning Coal-Derived Low-Btu Gaseous Fuels,” Trans. Jpn. Soc. Mech. Eng., Ser. B, 56, No. 532, pp. 3903–3909.
Sato,  M., Nakata,  T., Yoshine,  T., and Yamada,  M., 1991, “Development of a 1300 °C-Class Gas Turbine Combustor Burning Coal-Derived Low-Btu Gaseous Fuels,” Trans. Jpn. Soc. Mech. Eng., Ser. B, 57, No. 535, pp. 803–810.
Nakata,  T., Sato,  M., Ninomiya,  T., Yoshine,  T., and Yamada,  M., 1992, “Development of a 1300 °C-Class Gas Turbine Combustor Burning Coal-Derived Low-Btu Gaseous Fuels,” Trans. Jpn. Soc. Mech. Eng., Ser. B, 58, No. 553, pp. 2890–2897.
Nakata, T., Sato, M., and Hasegawa, T., 1994, “A Study on Low NOx Combustion in LBG-Fueled 1500 °C-Class Gas Turbine,” ASME Paper 94-GT-218.
Hasegawa, T., Sato, M., and Ninomiya, T., 1997, “Effect of Pressure on Emission Characteristics in LBG-Fueled 1500 °C-Class Gas Turbine,” ASME Paper 97-GT-277.
Hasegawa, T., Hisarnatsu, T., Katsuki, Y., Sato, M., Yamada, M., Onoda, A., and Utsunomiya, M., 1998, “A Study of Low NOx Combustion Characteristics in Medium-Btu Fueled 1300 °C-Class Gas Turbine Combustor,” ASME Paper 98-GT-331.
Modern Power Systems Review, 1993, “Clean Coal 5 Eyes BGL Gasification at Camden,” August 1993, pp. 21–24.
Kalsall,  G. J., Smith,  M. A., and Cannon,  M. F., 1994, “Low Emissions Combustor Development for an Industrial Gas Turbine to Utilize LCV Fuel Gas,” Trans. ASME J. Eng. Gas Turbines Power, 116, p. 559.
Ichikawa, K., and Araki, S., 1996, “Test Results of the IGCC System by the 200T/D Nakoso Pilot Plant,” Proc. The 9th Thermal Engineering Symp., pp. 11–12.
Bush, W. V., Baker, D. C., and Tijm, P. J. A., 1991, “Shell Coal Gasification Plant(SCGP-1) Environmental Performance Results,” EPRI Interim Report No. GS-7397, Project 2695-1.
Ueda, T., Kida, E., Nakaya, Z., Shikata, T., Koyama, S., and Takagi, M., 1995, “Design of the HYCOL Gasifier,” Proc. Int. Conference Power Engineering-’95, pp. 242–247.
Modern Power Systems, 1994, “Biomass Looks Good for Gasification Process,” April 1994, pp. 61–65.
Consonni, S., Larson, E. D., and Berglin, N., 1997, “Black Liquor-Gasifier/Gas Turbine Cogeneration,” ASME Paper 97-GT-273.
Ashizawa, M., Takahashi, T., Taki, M., Mori, K., Kanehira, S., and Takeno, K., 1996, “A Study, on Orimulsion Gasification Technology,” Power-Gen ’96 Int., 8 , pp. 235–243.
Hasegawa,  T., and Sato,  M., 1997, “Study on NOx Formation Characteristics of Medium Btu Coal Gasified Fuel,” Trans. Jpn. Soc. Mech. Eng., Ser. B, 63, No. 613, pp. 3123–3130.
Miller,  J. A., and Bowman,  C. T., 1989, “Mechanism and Modeling of Nitrogen Chemistry in Combustion,” Prog. Energy Combust. Sci., 15, pp. 287–338.
Hasegawa,  T., and Sato,  M., 1998, “Study of Ammonia Removal from Coal-Gasified Fuel,” Combust. Flame, 114, pp. 246–258.
Chase, Jr., M. W., Davies, C. A., Downey, Jr., J. R., Frurip, D. J., McDonald, R. A., and Syverud, A. N., 1985, “JANAF Thermodynamical tables 3rd Edition.,” J. Phys. Chem. Ref. Data, 14 .
Kee, R. J., Rupley, F. M., and Miller, J. A., 1990, Sandia Report, SAND 87-8215B.
Hindmarsh, A. C., 1974, Lawrence Livermore Laboratory, Univ. California, Report No. UCID-30001, Rev. 3.
Pratt, D. T., Bowman, B. R., and Crowe, C. T., 1971, AIAA paper 71-713.
Martin, F. J., and Dederick, P. K., 1977, “NOx From Fuel Nitrogen in Two-Stage Combustion,” Proc. 16th Symp. (Int.) on Comb., The Comb. Institute., Pittsburg, PA, pp. 191–198.
Yamagishi, K., Nozawa, M., Yoshie, T., Tokumoto, T., and Kanegawa, Y., 1974, “A Study of NOx Emission Characteristics in Two-Stage Combustion,” Proc. 15th Symp. (Int.) on Comb., The Comb. Institute., Pittsburgh, PA, pp. 1157–1165
JSME Data Book: Formation Mechanisms and Controls of Pollutants in Combustion System, 1980, 47 , JSME, Japan.
Sarofim,  A. F., Williams,  G. C., Modell,  M., and Slater,  S. M., 1975, “Conversion of Fuel Nitrogen to Nitric Oxide in Premixed and Diffusion Flames,” AIchE Symp. Ser., 71, No. 148, pp. 51–61.
Kato,  K., Fujii,  K., Kurata,  T., and Mori,  K., 1976, Trans. Jpn. Soc. Mech. Eng., 42, No. 354, pp. 582–589.
Fenimore,  C. P., 1972, “Formation of Nitric Oxide From Fuel Nitrogen in Ethylene Flames,” Combust. Flame, 19, No. 2, pp. 289–296.
Takagi,  T., Ogasawara,  M., Daizo,  M., and Tatsumi,  T., 1977, Trans. Jpn. Soc. Mech. Eng., 43, No. 368, p. 1426–1439.
Fenimore, C. P., 1976, “Effects of Diluents and Mixing on Nitric Oxide from Fuel-Nitrogen Species in Diffusion Flames,” Proc. 16th Symp. (Int.) on Comb., The Comb. Institute., Pittsburgh, PA, pp. 1065–1071.
Heap, M. P., Tyson, T. J., Cichanowicz, E., Gershman, R., Kau, C. J., Martin, G. B., and Lanier, W. S., 1976, “Environmental Aspects of Low BTU Gas Combustion,” Proc. 16th Symp. (Int.) on Comb., The Comb. Institute., Pittsburgh, PA, pp. 535–545.
Takagi,  T., Tatsumi,  T., Ogasawara,  M., and Tatsumi,  K., 1978, Trans. Jpn. Soc. Mech. Eng., 44, No. 388, pp. 4282–4291.
Kato,  K., Fujii,  K., Kurata,  T., and Mori,  K., 1977, Trans. Jpn. Soc. Mech. Eng., 43, No. 365, pp. 280–292.
Takagi, T., Ogasawara, M., Daizo, M., and Tatsumi, T., 1976, “NOx Formation From Nitrogen in Fuel and Air During Turbulent Diffusion Combustion,” Proc. 16th Symp. (Int.) Combust., The Comb. Institute, Pittsburgh, PA, pp. 181–188.

Figures

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Schematic diagram of experimental device
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Adiabatic flame temperature
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Effects of CO/H2 molar ratio in the fuel on adiabatic flame temperature
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NOx emission characteristics in low-Btu gas flame
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Effects of CO/H2 molar ratio on the conversion rate of NH3 in the fuel to NOx defining by the experiments
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Effects of CO/H2 molar ratio in the fuel on CO emission characteristics defining by the experiments
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Effects of NH3 concentration in the fuel on the conversion rate of NH3 in the fuel to NOx defining by the experiments
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Effect of NH3 concentration on the conversion rate of NH3 in the fuel to NOx with CH4 concentration and CO/H2 molar ratio as parameters defining by the experiments
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Effects of fuel calorific value on NOx emission characteristics from nitrogen fixation defining by the experiments
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Effects of fuel calorific value on the conversion rate of NH3 in the fuel to NOx and NOx emission defining by the experiments
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NOx emission characteristics in two-staged combustion defining by the experiments
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Effect of CO/H2 molar ratio on the conversion rate of NH3 in the fuel to NOx in two-staged combustion defining by the experiments
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Effect of CH4 concentration on the conversion rate of NH3 in the fuel to NOx in two-staged combustion defining by the experiments
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Mole fraction-time products, comparing ϕ p=0.6, 2.0 in two-stage combustion as defined by the calculation
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Effect of CH4 concentration on the conversion rate of NH3 in the fuel to NOx and CO emission characteristics in two-staged combustion defining by the experiments
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Effect of CH4 concentration on CO emission characteristics in two-staged combustion defining by the experiments
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Effect of fuel calorific value on NOx emission characteristics from nitrogen fixation in two-staged combustion defining by the experiments
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Effect of fuel calorific value on the conversion rate of NH3 in the fuel to NOx in two-staged combustion defining by the experiments
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Effect of pressure on the conversion rate of NH3 in the fuel to NOx and thermal-NOx emission characteristics in a real combustor
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Effect of pressure on CO emission characteristics in a real combustor

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