Plasma-Assisted Combustion Studies at AFRL

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Plasma-Assisted Combustion Studies at AFRL MURI Kickoff Meeting 4 November 2009 Cam Carter, Tim Ombrello & Mike Brown* Aerospace Propulsion Division Propulsion Directorate Air Force Research Laboratory *With contributions from S. Adams, M. Gundersen et al., B. Ganguly & T. Lee

Overview Areas where plasmas and E-fields can have an influence Enhance reaction rate & flamespeed Important for high-speed combustors (& other combustors too): Ignition, from cold state especially & with liquid fuel Steady operation, through flamespeed enhancement and flameholding Potentially important for lean, gas-turbine (powerplant) operation Might one also mitigate/influence acoustic fluctuations? Potential for uniform performance with nonuniform fuel source Enhance fuel-air mixing & penetration Potential alternative to intrusive mechanisms (struts/pylons) Potential for dynamic control of penetration/mixing Potential for creating recirculation region for flameholding Boundary-layer & surface interactions Trip boundary layer; hold shock 2

HC sources provide ~85% of nation s energy 97% for transportation Transportation s consumption about 28% of total 1 million gallons/minute Quads = quadrillion (10 15 ) BTU 10 18 J Overview Fun Facts on US Energy Consumption US Energy Consumption, 1950-2005 Source: Energy Information Administration, Annual Energy Review 2005, Report DOE/EIA-0384 (2005). See also Report of the Basic Energy Sciences Workshop on Basic Research Needs for Clean and Efficient Combustion of 21 st Century Transportation Fuels 3

Overview Plasma/E-field Effects on Ignition & Flame Behavior -W E-field Effects on Flame Propagation Stockman, Miles, Zaidi (Princeton), Ryan Diagnostics of Plasma Enhanced Flames Lee (MSU) No -W Pulsed -W Planar FRS Thermometry with pulsed -W Source Direct coupled plasma torch: flame OH vs. -wave power: Plasma-assisted Ignition Cathey, Gundersen, Wang, Cain (USC), Ryan Combustion Chamber Effects of Gliding Arc on Flame Chemistry Ombrello, Ju (Princeton), Gutsol, Fridman, (Drexel) P = 78 W a = 127 s -1 Ignition event 4

Enhancement of Flamespeed through Plasma Activation* Goal: Study flame propagation increase with plasma-excited oxidizer Integrate plasma source with custom Hencken burner Gases mix at burner exit Quartz coating of metal surfaces Operate at low P Reduced reaction rates Allow mixing of fuel & oxidizer upstream of flame *Ombrello, Ju, Sun, Carter, Brown, Katta 5

Enhancement of Flamespeed through Plasma Activation* Decrease chamber P to lift flame from surface Flame has fully premixed character at low P Apply diagnostics to characterize plasma species, T & V Species of interest: O 3, O 2 (a 1 g), O 2 (b 1 g), O, O( 1 D) *Ombrello, Ju, Sun, Carter, Brown, Katta 6

Enhancement of Flamespeed through Plasma Activation* P 2 ignition system lifted flame camera φ=1 vacuum pump FTIR O 3 Absorption Cell vacuum pump C 3 H 8 or C 2 H 4 O 2 Ar P 1 ICOS Cavity T 3 T 2 T 1 fuel oxidizer microwave power supply 3-way valve NO Increasing Fuel Jet Velocity Nozzle Tip Use low-p lifted jet flame: lift-off height H L sensitive to flamespeed, S L Characterize S L increase with H L measurement Produce & quantify O 3 and O 2 (a 1 g) measure H L *Ombrello, Ju, Won, Williams 7

Enhancement of Flamespeed through Plasma Activation* ΔH L [mm] Graph shows isolated effect of O 3 and O 2 (a 1 g) P = 27 or 51 Torr Concentrations of O 2 (a 1 g) as large as ~X = 0.6% Conversion of H L to S L requires additional measurements and/or modeling Work with Hencken flame will be follow-on effort 8 7 6 5 4 3 2 1 0 27.1 Torr 50.5 Torr O3 3 (exp.) O2(a) 2 1 Δ(exp.) g ) (exp.) O3 3 (exp.) O2(a) 2 1 Δ(exp.) g ) (exp.) 0 1000 2000 3000 4000 5000 6000 7000 Concentration [ppm] *Ombrello, Ju, Won, Williams 8

Ignition Enhancement with Transient Plasma (TP)* Goal: Determine physical mechanism, primarily for transient plasma ignition What is role of humidity: X H2O affects detonation wave speed in PDE but not t ign Measure X OH and X O3 vs. X H2O in air OH from PLIF & O 3 from absorption Need to sample along anode, especially since flame originates from anode surface Highly desirable: O-atom distribution Also CH 3 and CH 2 O Combustion chamber Variable anode lengths & materials Optical access: windowed-slits (not shown) & end-flange window *Singleton, Pendleton, Gundersen (USC), Stockman, Carter, Brown 9

Ignition Enhancement with TP* stoichiometric C 2 H 4 -air P = 1 atm E pulse = 550 mj (75 kv) t pulse 100 ns Effect of anode length & comparison to spark plug (2 cm from back wall) Significant reduction in t ign even with 3-mm length protrusion Flame propagates from anode to wall Flame initiation and propagation approx. uniform along perimeter & length *Singleton, Pendleton, Gundersen (USC), Stockman, Carter, Brown 10

Ignition Enhancement with TP* Anode Field of View Laser sheet window slits Camera looking down into chamber Continuous flow of moist air 1-Hz pulse frequency X H2O measured with TDLAS PLIF of OH: Peak signals ~10 15 cm -3 *Singleton, Pendleton, Gundersen (USC), Stockman, Carter, Brown 11

Ignition Enhancement with TP* anode Camera looking down into chamber Continuous flow of moist air 1-Hz pulse frequency X H2O measured with TDLAS PLIF of OH: Peak signals ~10 15 cm -3 *Singleton, Pendleton, Gundersen (USC), Stockman, Carter, Brown 12

X O3 (ppm) Ignition Enhancement with TP* washeranode LED beam PD Line-of-sight average concentration UV LED beam positioned over washer Undetectable X O3 with normal config. 1-ms LED pulse synched to TPI pulse 200 o-scope waveforms recorded Presumably, X O3 distribution nonuniform *Singleton, Pendleton, Gundersen (USC), Stockman, Carter, Brown time ( s) 13

Resonant Laser Induced Breakdown for Fuel-Air Ignition* Goal: Investigate effectiveness of low-energy REMPI laser pulse to control spatial & temporal behavior of ignition spark in air crossflow Approach: Apply potential (below breakdown value) Focus UV laser pulse at REMPI transition & ionize channel between gap 1-5 cm 70 Lens Cathode Anode Air Flow To be presented at ASM-2010 *S. Adams, J. Miles, and A. Laber (AFRL/RZPE) 14

Resonant Laser Induced Breakdown for Fuel-Air Ignition* Sample photo of a laser induced arc Main arc follows laser path Secondary arcs & plasma glow occur after main arc; result of leakage current as capacitor recharges 5 cm *S. Adams, J. Miles, and A. Laber (AFRL/RZPE) 15

Non-thermal Plasmas to Modify Combustion Kinetics* Goal: Study effect of pulsed plasma on a C 3 H 8 /air Bunsen flame Quantify with phase-averaged Raman scattering and CH chemiluminescence & time-resolved OH chemiluminescence V-I Characteristics ICCD PMT OH Plasma Emission burner *B. Ganguly, J. Schmidt (AFRL/RZPE) 16

Non-thermal Plasmas to Modify Combustion Kinetics* Bunsen Burner Goal: Study effect of pulsed plasma on a C 3 H 8 /air Bunsen flame Quantify with phase-averaged Raman scattering and CH chemiluminescence & time-resolved OH chemiluminescence V-I Characteristics Electrode Raman probe beam Unperturbed (no voltage) OH Plasma Emission C 3 H 8 -air *B. Ganguly, J. Schmidt (AFRL/RZPE) 17

Non-thermal Plasmas to Modify Combustion Kinetics* Bunsen Burner Goal: Study effect of pulsed plasma on a C 3 H 8 /air Bunsen flame Quantify with phase-averaged Raman scattering and CH chemiluminescence & time-resolved OH chemiluminescence V-I Characteristics Electrode Raman probe beam Voltage applied; plasma formed OH Plasma Emission C 3 H 8 -air *B. Ganguly, J. Schmidt (AFRL/RZPE) 18

Temperature [K] CH emission intensity (arb unit) Non-thermal Plasmas to Modify Combustion Kinetics* 200 Hz rep rate pulsed discharge Few mj of energy input; significant perturbation Intensity Map for Selected Images Phase-locked measurement of T and CH chemiluminescence. 2000 50 Finite response of flame; some recovery before next pulse Temp -vs- Avg. Image Int. 100 150 200 250 1400 1200 Image area (overlap laser probe) 1800 300 1000 350 800 1600 1400 0 1 2 3 4 5 6 7 8 9 10 Discharge Delay [ms] 400 450 500 Temp ImageT 600 400 200 Flame perturbed by pulsed plasma 50 100 150 200 250 300 350 400 450 500 *B. Ganguly, J. Schmidt (AFRL/RZPE) 19

Summary Three final thoughts: Understanding the role of electric fields, plasma & plasma-derived species in initiating and sustaining combustion of critical importance to more effective use Potential for impacting many areas related to use of hydrocarbons We (AFRL) welcome collaborations! Many already with MURI team members We ll even do some crazy stuff Good luck on efforts! 20

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