This paper studies different IGCC systems with CO2 recovery. In order to effectively reduce CO2 emissions from the IGCC system, several kinds of IGCC systems with quasizero CO2 emissions have been studied in this paper. The key parameters affecting the IGCC systems’ performance have been analyzed and compared. The systems’ performances have been investigated based on comparison of different IGCC systems. The obtained results show that integrating the IGCC system with an advanced thermal cycle is an effective and feasible way. The performances of the IGCC systems with O2/CO2 cycle and syngas separation are better than that with a simple semi-closed O2/CO2 cycle. The research achievements will provide valuable information for further study on IGCC systems with low CO2 emissions.
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Campanari, S., Macchi, E., “Thermodynamic analysis of advanced power cycles based upon solid oxide fuel cells, gas turbines and rankine bottoming Mechanical Engineers (Paper), GT, 98-GT-585, , p. 12. Society of Chiesa, P., Lozza, G., “CO2 Emission Abatement in IGCC Power Plants by Semi-closed Cycles. Part A: With Oxygen-blown Combustion”, 1998. ASME 98-GT-384.
Dawn, S., Ian, R., “Parametric study of fuel cell and gas turbine combined cycle performance”. American Society of Mechanical Engineers (Paper), 97-GT-340, 1997, p. 10.
Duan L., Lin, R., Cai, R., Jin, H., “Research Development of Integrated Gasification Combined Cycle (IGCC) with quasi-zero CO2 emission”. Gas Turbine Technology, 2002. V. 15, No. 3, pp. 31-35.
Duan, L., Lin, R., Deng, S., Jin, H., and Cai, R., “A Novel IGCC system with steam-injected H2/O2 cycle and CO2 recovery”, The International Journal of Energy Conversion and Management, , Vol. 45, No. 6, pp. 797-809. Jin, H., Ishida, M., “A Novel Gas Turbine Cycle with Combustion”. International Journal of Hydrogen Energy. 2000. pp. 1209-1215. Chemical-looping
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Massardo, A. F., McDonald, C. F., Korakianitis T., “Microturbine/Fuel-Cell Coupling for High- Efficiency Electrical-Power Generation”. Journal of Engineering for Gas Turbines and Power 2002, Vol. 124, pp. 110-116.
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Year 2007,
Volume: 10 Issue: 2, 61 - 69, 01.06.2007
Balachandran, U., Guan, J., Dorris, S. E. “Development of proton-conducting membranes for hydrogen separation”. ANL Program Report, , W-31-109-eng-38. Bevc, F., Wayne L. L., Dennis, M. B., “Solid oxide fuel cell combined cycles”. American Society of Mechanical Engineers (Paper), 96-GT-447, 1996, p. 6.
Bose, A., Sammells, A., “Separating hydrogen from industrial gases in an environmentally benign process”. 2000, U.S.DOE NETL project facts. inexpensive,
Campanari, S., Macchi, E., “Thermodynamic analysis of advanced power cycles based upon solid oxide fuel cells, gas turbines and rankine bottoming Mechanical Engineers (Paper), GT, 98-GT-585, , p. 12. Society of Chiesa, P., Lozza, G., “CO2 Emission Abatement in IGCC Power Plants by Semi-closed Cycles. Part A: With Oxygen-blown Combustion”, 1998. ASME 98-GT-384.
Dawn, S., Ian, R., “Parametric study of fuel cell and gas turbine combined cycle performance”. American Society of Mechanical Engineers (Paper), 97-GT-340, 1997, p. 10.
Duan L., Lin, R., Cai, R., Jin, H., “Research Development of Integrated Gasification Combined Cycle (IGCC) with quasi-zero CO2 emission”. Gas Turbine Technology, 2002. V. 15, No. 3, pp. 31-35.
Duan, L., Lin, R., Deng, S., Jin, H., and Cai, R., “A Novel IGCC system with steam-injected H2/O2 cycle and CO2 recovery”, The International Journal of Energy Conversion and Management, , Vol. 45, No. 6, pp. 797-809. Jin, H., Ishida, M., “A Novel Gas Turbine Cycle with Combustion”. International Journal of Hydrogen Energy. 2000. pp. 1209-1215. Chemical-looping
Jurado, F., “Study of molten carbonate fuel cell— microturbine hybrid power cycles”. Journal of Power Sources, 2002, 111, pp. 121–129.
Lin, R., Duan, L., Jin, H., “Exploit Study on IGCC System with few CO2 emissions”, Journal of Engineering Thermophysics, 2002. Vol. 23, No. 6, pp. 661-664.
Massardo, A. F., McDonald, C. F., Korakianitis T., “Microturbine/Fuel-Cell Coupling for High- Efficiency Electrical-Power Generation”. Journal of Engineering for Gas Turbines and Power 2002, Vol. 124, pp. 110-116.
Mathieu, P., Van L. F., “Modeling of an IGCC plant based on an oxy-fuel combustion combined cycle”, Clean coal technologies 2005, Cagliari, Sardinia, Italy.
Mathieu, P., Van L. F., “Comparison of a zero emission IGCC power plant with an IGCC with pre-combustion Conference, Lisbon. Clean Air Roark, S., Mackay, R., and Sammells, A., Eltron Research, Inc., “Hydrogen Separation Membranes for Vision 21 Fossil Fuel Plants”, The 27th International Utilization & Fuel Systems, 2002 Conference on Coal
Duan, L., Yang, Y., & Lin, R. (2007). Comparative Study on Different IGCC Systems with Quasi-Zero CO2 Emission. International Journal of Thermodynamics, 10(2), 61-69.
AMA
Duan L, Yang Y, Lin R. Comparative Study on Different IGCC Systems with Quasi-Zero CO2 Emission. International Journal of Thermodynamics. June 2007;10(2):61-69.
Chicago
Duan, Liqiang, Yongping Yang, and Rumou Lin. “Comparative Study on Different IGCC Systems With Quasi-Zero CO2 Emission”. International Journal of Thermodynamics 10, no. 2 (June 2007): 61-69.
EndNote
Duan L, Yang Y, Lin R (June 1, 2007) Comparative Study on Different IGCC Systems with Quasi-Zero CO2 Emission. International Journal of Thermodynamics 10 2 61–69.
IEEE
L. Duan, Y. Yang, and R. Lin, “Comparative Study on Different IGCC Systems with Quasi-Zero CO2 Emission”, International Journal of Thermodynamics, vol. 10, no. 2, pp. 61–69, 2007.
ISNAD
Duan, Liqiang et al. “Comparative Study on Different IGCC Systems With Quasi-Zero CO2 Emission”. International Journal of Thermodynamics 10/2 (June 2007), 61-69.
JAMA
Duan L, Yang Y, Lin R. Comparative Study on Different IGCC Systems with Quasi-Zero CO2 Emission. International Journal of Thermodynamics. 2007;10:61–69.
MLA
Duan, Liqiang et al. “Comparative Study on Different IGCC Systems With Quasi-Zero CO2 Emission”. International Journal of Thermodynamics, vol. 10, no. 2, 2007, pp. 61-69.
Vancouver
Duan L, Yang Y, Lin R. Comparative Study on Different IGCC Systems with Quasi-Zero CO2 Emission. International Journal of Thermodynamics. 2007;10(2):61-9.