Fuel composition has a strong influence on the turbulent flame speed, even at very high turbulence intensities. An important implication of this result is that the turbulent flame speed cannot be extrapolated from one fuel to the next using only the laminar flame speed and turbulence intensity as scaling variables. This paper presents curvature and tangential strain rate statistics of premixed turbulent flames for high hydrogen content (HHC) fuels. Global (unconditioned) stretch statistics are presented as well as measurements conditioned on the leading points of the flame front. These measurements are motivated by previous experimental and theoretical work that suggests the turbulent flame speed is controlled by the flame front characteristics at these points. The data were acquired with high-speed particle image velocimetry (PIV) in a low-swirl burner (LSB). We attained measurements for several H2:CO mixtures over a range of mean flow velocities and turbulence intensities. The results show that fuel composition has a systematic, yet weak effect on curvatures and tangential strain rates at the leading points. Instead, stretch statistics at the leading points are more strongly influenced by mean flow velocity and turbulence level. It has been argued that the increased turbulent flame speeds seen with increasing hydrogen content are the result of increasing flame stretch rates, and therefore, SL,max values, at the flame leading points. However, the differences observed with changing fuel compositions are not significant enough to support this hypothesis. Additional analysis is needed to understand the physical mechanisms through which the turbulent flame speed is altered by fuel composition effects.
Skip Nav Destination
Article navigation
November 2017
Research-Article
Measurements of Stretch Statistics at Flame Leading Points for High Hydrogen Content Fuels
Andrew Marshall,
Andrew Marshall
School of Mechanical Engineering,
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: andrew.marshall@siemens.com
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: andrew.marshall@siemens.com
Search for other works by this author on:
Jerry Seitzman,
Jerry Seitzman
School of Aerospace Engineering,
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: jerry.seitzman@ae.gatech.edu
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: jerry.seitzman@ae.gatech.edu
Search for other works by this author on:
Tim Lieuwen
Tim Lieuwen
School of Aerospace Engineering,
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: tim.lieuwen@aerospace.gatech.edu
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: tim.lieuwen@aerospace.gatech.edu
Search for other works by this author on:
Andrew Marshall
School of Mechanical Engineering,
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: andrew.marshall@siemens.com
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: andrew.marshall@siemens.com
Julia Lundrigan
Prabhakar Venkateswaran
Jerry Seitzman
School of Aerospace Engineering,
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: jerry.seitzman@ae.gatech.edu
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: jerry.seitzman@ae.gatech.edu
Tim Lieuwen
School of Aerospace Engineering,
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: tim.lieuwen@aerospace.gatech.edu
Georgia Institute of Technology,
Atlanta, GA 30332
e-mail: tim.lieuwen@aerospace.gatech.edu
1Present address: Siemens Energy, Inc., Charlotte, NC 28273.
Contributed by the Combustion and Fuels Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received October 24, 2015; final manuscript received January 3, 2017; published online July 6, 2017. Editor: David Wisler.
J. Eng. Gas Turbines Power. Nov 2017, 139(11): 111503 (11 pages)
Published Online: July 6, 2017
Article history
Received:
October 24, 2015
Revised:
January 3, 2017
Citation
Marshall, A., Lundrigan, J., Venkateswaran, P., Seitzman, J., and Lieuwen, T. (July 6, 2017). "Measurements of Stretch Statistics at Flame Leading Points for High Hydrogen Content Fuels." ASME. J. Eng. Gas Turbines Power. November 2017; 139(11): 111503. https://doi.org/10.1115/1.4035819
Download citation file:
Get Email Alerts
Cited By
Temperature Dependence of Aerated Turbine Lubricating Oil Degradation from a Lab-Scale Test Rig
J. Eng. Gas Turbines Power
Multi-Disciplinary Surrogate-Based Optimization of a Compressor Rotor Blade Considering Ice Impact
J. Eng. Gas Turbines Power
Experimental Investigations on Carbon Segmented Seals With Smooth and Pocketed Pads
J. Eng. Gas Turbines Power
Related Articles
Displacement Speed Statistics for Stratified Mixture Combustion in an Igniting Turbulent Planar Jet
J. Eng. Gas Turbines Power (May,2012)
Subgrid Scale Combustion Modeling Based on Stochastic Model Parameterization
J. Eng. Gas Turbines Power (March,2012)
Flashback in Lean Prevaporized Premixed Combustion: Nonswirling Turbulent Pipe Flow Study
J. Eng. Gas Turbines Power (July,2003)
A Large-Eddy Simulation–Linear-Eddy Model Study of Preferential Diffusion Processes in a Partially Premixed Swirling Combustor With Synthesis Gases
J. Eng. Gas Turbines Power (March,2017)
Related Proceedings Papers
Related Chapters
Cavitating Structures at Inception in Turbulent Shear Flow
Proceedings of the 10th International Symposium on Cavitation (CAV2018)
Physiology of Human Power Generation
Design of Human Powered Vehicles
Mass Data Processing Optimization on High Energy Physics Experiments
International Conference on Advanced Computer Theory and Engineering, 4th (ICACTE 2011)