Gas turbines in integrated gasification combined cycle power plants burn a fuel gas (syngas (SG)) in which the proportions of hydrocarbons, , CO, water vapor, and minor impurity levels may differ significantly from those in natural gas (NG). Such differences can yield changes in the temperature, pressure, and corrosive species that are experienced by critical components in the hot gas path, with important implications for the design, operation, and reliability of the turbine. A new data structure and computational methodology is presented for the numerical simulation of a turbine thermodynamic cycle, with emphasis on the hot gas path components. The approach used allows efficient handling of turbine components and variable constraints due to fuel changes. Examples are presented for a turbine with four stages, in which the vanes and blades are cooled in an open circuit using air from the appropriate compressor stages. For an imposed maximum metal temperature, values were calculated for the fuel, air, and coolant flow rates and through-wall temperature gradients for cases where the turbine was fired with NG or SG. A NG case conducted to assess the effect of coolant pressure matching between the compressor extraction points and corresponding turbine injection points indicated that this is a feature that must be considered for high combustion temperatures. The first series of SG simulations was conducted using the same inlet mass flow and pressure ratios as those for the NG case. The results showed that higher coolant flow rates and a larger number of cooled turbine rows were needed for the SG case to comply with the imposed temperature constraints. Thus, for that case, the turbine size would be different for SG than for NG. A second series of simulations examined scenarios for maintaining the original turbine configuration (i.e., geometry, diameters, blade heights, angles, and cooling circuit characteristics) used for the SG simulations. In these, the inlet mass flow was varied while keeping constant the pressure ratios and the amount of hot gas passing the first vane of the turbine. The effects of turbine matching between the NG and SG cases were increases—for the SG case of approximately 7% and 13% for total cooling flows and cooling flows for the first-stage vane, respectively. In particular, for the SG case, the vanes in the last stage of the turbine experienced inner wall temperatures that approached the maximum allowable limit.
Skip Nav Destination
Article navigation
July 2009
Technical Briefs
The Effects of Changing Fuels on Hot Gas Path Conditions in Syngas Turbines
Adrian S. Sabau,
Adrian S. Sabau
Materials and Science and Technology Division,
Oak Ridge National Laboratory
, Oak Ridge, TN 37831
Search for other works by this author on:
Ian G. Wright
Ian G. Wright
Materials and Science and Technology Division,
Oak Ridge National Laboratory
, Oak Ridge, TN 37831
Search for other works by this author on:
Adrian S. Sabau
Materials and Science and Technology Division,
Oak Ridge National Laboratory
, Oak Ridge, TN 37831
Ian G. Wright
Materials and Science and Technology Division,
Oak Ridge National Laboratory
, Oak Ridge, TN 37831J. Eng. Gas Turbines Power. Jul 2009, 131(4): 044501 (7 pages)
Published Online: April 14, 2009
Article history
Received:
May 13, 2008
Revised:
May 14, 2008
Published:
April 14, 2009
Citation
Sabau, A. S., and Wright, I. G. (April 14, 2009). "The Effects of Changing Fuels on Hot Gas Path Conditions in Syngas Turbines." ASME. J. Eng. Gas Turbines Power. July 2009; 131(4): 044501. https://doi.org/10.1115/1.3028566
Download citation file:
Get Email Alerts
Cited By
On Leakage Flows In A Liquid Hydrogen Multi-Stage Pump for Aircraft Engine Applications
J. Eng. Gas Turbines Power
A Computational Study of Temperature Driven Low Engine Order Forced Response In High Pressure Turbines
J. Eng. Gas Turbines Power
The Role of the Working Fluid and Non-Ideal Thermodynamic Effects on Performance of Gas Lubricated Bearings
J. Eng. Gas Turbines Power
Tool wear prediction in broaching based on tool geometry
J. Eng. Gas Turbines Power
Related Articles
Qualitative and Quantitative Comparison of Two Promising Oxy-Fuel Power Cycles for C O 2 Capture
J. Eng. Gas Turbines Power (May,2008)
Aspects of Cooled Gas Turbine Modeling for the Semi-Closed O 2 / CO 2 Cycle With CO 2 Capture
J. Eng. Gas Turbines Power (July,2004)
Application of “H Gas Turbine” Design Technology to Increase Thermal Efficiency and Output Capability of the Mitsubishi M701G2 Gas Turbine
J. Eng. Gas Turbines Power (April,2005)
Effects of a Reacting Cross-Stream on Turbine Film Cooling
J. Eng. Gas Turbines Power (May,2010)
Related Chapters
Introduction
Consensus on Operating Practices for Control of Water and Steam Chemistry in Combined Cycle and Cogeneration
Control and Operational Performance
Closed-Cycle Gas Turbines: Operating Experience and Future Potential
Combined Cycle Power Plant
Energy and Power Generation Handbook: Established and Emerging Technologies