Laminar Boundary Layers behind Blast and Detonation Waves.

Abstract

The transformed coordinates devised by Mirels and Hamman have been modified in such a way that the transformed nonstationary-boundary-layer equations become applicable to boundary-layer flows induced by both blast and detonation waves moving with a power-law trajectory in planar, cylindrical and spherical geometries. Investigations were made of boundary-layer flows in air behind nonuniform strong blast waves and in the burned gas of a stoichiometric mixture of hydrogen and oxygen behind uniform Chapman-Jouguet detonation waves. The results show that the Prandtl number has a profound influence on boundary-layer flow. For a blast wave and Pr less than unity it controls a boundary-layer velocity-overshoot as one moves away from the wave. The overshoot decreases with increasing Prandtl number. For a Chapman-Jouguet detonation wave similar results are obtained for a Pr = 0.72. However, for an actual Pr = 2.26, a flow reversal occurs away from the wave where the inviscid flow velocity approaches a small value. In order to show some of the physical features of the various boundary layers, actual velocity profiles were computed for spherical and planar detonation waves in stoichiometric hydrogen-oxygen and for blast waves in air. In order to test the validity of the analysis, the heat transfer to the wall behind a planar detonation wave was calculated. The profile of the variation of the heat transfer with time at any given position behind a C-J detonation wave is in good agreement with the experimental data, and adds confidence to teh present analyses for cylindrical and spherical flows as well.

Document Details

Document Type

Technical Report

Publication Date

Aug 01, 1982

Accession Number

ADA127456

Entities

Tags