Wave Drag Reduction of Blunt Bodies Using Laser Sustained Energy Deposition In Argon Atmosphere

Sperber, David; Schmid, Fabian; Eckel, Hans‐Albert; Fasoulas, Stefanos

doi:10.2514/6.2012-2815

Cited by 2 publications

(1 citation statement)

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“…Both measurement techniques disregard reflection and refraction losses of the transmitted laser beam. = 1 ± 0.13 for Mach 2.7 at p 2 = 6.6 bar and η = 0.58 ± 0.14 for Mach 2.1 at p 2 = 6.2 bar, using w ∞ for the free jet velocity [23]. The amount of deposited energy versus stagnation pressure is comparable for Mach 2.1 and Mach 2.7.…”

Section: Streaming Gas Conditionsmentioning

confidence: 87%

Objectives of Laser‐Induced Energy Deposition for Active Flow Control

Sperber

Eckel

Steimer

et al. 2012

Contrib. Plasma Phys.

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A highly concentrated energy deposition has been proposed for a flow control concept in super-and hypersonic transportation. The plasma source can be implemented by laser-, microwave-or DC-discharge phenomena in the flow field upstream of a blunt body. In a wide range of Mach numbers the thermal modification of the gas condition mitigates the strength of the shock waves and improves the aerodynamic performance. This paper presents a discussion of the methodology and objectives of laser-induced energy deposition particularly with regard to the generation of laser-sustained plasma in supersonics. A steady-state argon plasma is maintained by an intensity field in the focal region of a continuous wave laser. The experimental results using drag, laser energy transmission and plasma radiation measurements determine the requirements for laser-sustained plasma and validate the control authority of this concept.

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Section: Streaming Gas Conditionsmentioning

confidence: 87%