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Experimental and theoretical study of the stability of plane shock waves reflected normally from perturbed flat walls

Published online by Cambridge University Press:  28 March 2006

M. G. Briscoe
Affiliation:
The Gas Dynamics Laboratory, Department of Mechanical Engineering and Astronautical Sciences, Northwestern University, Evanston, Illinois
A. A. Kovitz
Affiliation:
The Gas Dynamics Laboratory, Department of Mechanical Engineering and Astronautical Sciences, Northwestern University, Evanston, Illinois

Abstract

The rate of damping of perturbations on a shock wave reflected from a perturbed flat wall was measured in a shock tube. Incident shock wave Mach numbers of 1·45 and 1·09 in air together with sinusoidal and Gaussian wall perturbations were employed. These measurements were compared with a modified form of a linearized theory due to Zaidel (1960). The linearization was performed about the basic solution of a plane shock wave reflected normally from a flat wall.

The rate of decay and the frequency and phase of oscillations agreed very well with the theoretical predictions; the amplitudes of the oscillations were some-what larger than predicted. The reflected shock shape was initially in good agreement with theory, but higher frequency perturbations on the reflected shock front caused deviations from the predicted shape after the shock front had travelled about one wall-wavelength away from the wall.

The generally satisfactory agreement between theory and experiment supports the use of linearized analysis in predicting shock wave stability.

Type
Research Article
Copyright
© 1968 Cambridge University Press

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