To achieve very low emission levels, lean-premixed gas turbine combustors have been commercially implemented that operate near the fuel-lean flame extinction limit. Near the lean limit, however, flashback, lean blow off, and combustion dynamics have appeared as problems during operation. To help address these operational problems, a combustion control and diagnostics sensor (CCADS) for gas turbine combustors is being developed. CCADS uses the electrical properties of the flame to detect key events and monitor critical operating parameters within the combustor. Previous development efforts have shown the capability of CCADS to monitor flashback and equivalence ratio. Recent work has focused on detecting and measuring combustion instabilities. A highly instrumented atmospheric combustor has been used to measure the pressure oscillations in the combustor, the emission, and the flame ion field at the premix injector outlet and along the walls of the combustor. This instrumentation allows examination of the downstream extent of the combustion field using both the emission and the corresponding electron and ion distribution near the walls of the combustor. In most cases, the strongest pressure oscillation dominates the frequency behavior of the emission and the flame ion signals. Using this highly instrumented combustor, tests were run over a matrix of equivalence ratios from 0.6 to 0.8, with an inlet reference velocity of . The acoustics of the fuel system for the combustor were tuned using an active-passive technique with an adjustable quarter-wave resonator. Although several statistics were investigated for correlation with the dynamic pressure in the combustor, the best correlation was found with the standard deviation of the guard current. The data show a monotonic relationship between the standard deviation of the guard current (the current through the flame at the premix injector outlet) and the standard deviation of the chamber pressure. Therefore, the relationship between the standard deviation of the guard current and the standard deviation of the pressure is the most promising for monitoring the dynamic pressure of the combustor using the flame ionization signal. This addition to the capabilities of CCADS would allow for dynamic pressure monitoring on commercial gas turbines without a pressure transducer.
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e-mail: benjamin.chorpening@netl.doe.gov
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April 2007
Technical Papers
Combustion Oscillation Monitoring Using Flame Ionization in a Turbulent Premixed Combustor
B. T. Chorpening,
B. T. Chorpening
National Energy Technology Laboratory,
e-mail: benjamin.chorpening@netl.doe.gov
US Department of Energy
, Morgantown, WV 26507-0880
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J. D. Thornton,
J. D. Thornton
National Energy Technology Laboratory,
US Department of Energy
, Morgantown, WV 26507-0880
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E. D. Huckaby,
E. D. Huckaby
National Energy Technology Laboratory,
US Department of Energy
, Morgantown, WV 26507-0880
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K. J. Benson
K. J. Benson
Woodward
, Loveland, CO 80538
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B. T. Chorpening
National Energy Technology Laboratory,
US Department of Energy
, Morgantown, WV 26507-0880e-mail: benjamin.chorpening@netl.doe.gov
J. D. Thornton
National Energy Technology Laboratory,
US Department of Energy
, Morgantown, WV 26507-0880
E. D. Huckaby
National Energy Technology Laboratory,
US Department of Energy
, Morgantown, WV 26507-0880
K. J. Benson
Woodward
, Loveland, CO 80538J. Eng. Gas Turbines Power. Apr 2007, 129(2): 352-357 (6 pages)
Published Online: August 30, 2006
Article history
Received:
September 30, 2004
Revised:
August 30, 2006
Citation
Chorpening, B. T., Thornton, J. D., Huckaby, E. D., and Benson, K. J. (August 30, 2006). "Combustion Oscillation Monitoring Using Flame Ionization in a Turbulent Premixed Combustor." ASME. J. Eng. Gas Turbines Power. April 2007; 129(2): 352–357. https://doi.org/10.1115/1.2431390
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