Laser Spark Evolution in an Ethylene Jet in Supersonic Crossflow Configuration

Fries, Dan; Ranjan, Devesh; Menon, Suresh

doi:10.1007/s10494-022-00382-2

Flow Turbulence Combust

2022

DOI: 10.1007/s10494-022-00382-2

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Laser Spark Evolution in an Ethylene Jet in Supersonic Crossflow Configuration

Dan Fries

Devesh Ranjan

Suresh Menon

Abstract: Ignition and relighting in supersonic flows is an important challenge for the design of hypersonic propulsion systems. Supersonic compressible flows of interest exhibit much larger local variations in velocity, shear, and thermodynamic state than their incompressible counterparts. Thus, it is of interest to study the relationship between ignition kernel evolution, the initial spark location, and the kernel's subsequent flow state history. We leverage the flexibility of a laser plasma ignition system to systema… Show more

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2024

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Temperature Distribution Within an Ignition Kernel Initiated by a Laser-Induced Plasma

Jo,

Gore

2024

AIAA Journal

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The sizes of, and temperature distributions within, ignition kernels initiated by a Q-switched neodymium-doped yttrium aluminum garnet laser-induced plasma in an unconfined lean premixed hydrogen-air upward jet flow are investigated. The experiments involved a range of jet velocities and a range of deposited laser energies at a fixed height above the exit along the axis of a burner. The growth of, and the temperature distributions within, the ignition kernels, as affected by the size and the energy distribution of the laser-induced plasma, are monitored with an infrared camera. The initial ignition kernels’ areas are larger with higher laser pulse energies and remain unchanged up to [Formula: see text] and then increase by factors of up to 3 at [Formula: see text]. The change in the kernel area caused by the jet velocities is less than 1.5%. An increase of the bulk velocity by 190% decreases the ignition kernel temperature by 6%. This reduction in the ignition kernel temperatures is because of an increase in energy losses by a factor of 2 and decreases in heat releases by 2% at [Formula: see text] and by 11% at [Formula: see text]. The present contributions are: measurements of and insights into temperature distributions and kernel development rates during the laser-induced plasma ignition process at different deposited energies and flow velocities.

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Temperature Distribution Within an Ignition Kernel Initiated by a Laser-Induced Plasma

Jo,

Gore

2024

AIAA Journal

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Laser Spark Evolution in an Ethylene Jet in Supersonic Crossflow Configuration

Cited by 1 publication

References 43 publications

Temperature Distribution Within an Ignition Kernel Initiated by a Laser-Induced Plasma

Temperature Distribution Within an Ignition Kernel Initiated by a Laser-Induced Plasma

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