This article is cited in 27 papers

Dispersion of a cloud of particles by a moving shock: Effects of the shape, angle of rotation, and aspect ratio

S. L. Davis^a, T. B. Dittmann^a, G. B. Jacobs^a, W.-S. Don<sup>b

a</sup> San Diego State University, San Diego, CA, 92182, USA
^b Hong Kong Baptist University, Hong Kong, China

Abstract: This paper discusses the particle-laden flow development from a cloud of particles in an accelerated flow behind a normal moving shock. The effects of the aspect ratio of a rectangular and ellipsoidal cloud and the cloud's angle of attack with respect to the carrier flow are studied. Computations are performed with an in-house high-order weighted essentially non-oscillatory (WENO-Z) finite-difference scheme-based Eulerian–Lagrangian solver that solves the conservation equations in the Eulerian frame, while particles are traced in the Lagrangian frame. Streamlined elliptically shaped clouds exhibit a lower dispersion than blunt rectangular clouds. The averaged and root-mean-square locations of the particle coordinates in the cloud show that the cloud's streamwise convection velocity increases with decreasing aspect ratio. With increasing rotation angle, the cross-stream dispersion increases if the aspect ratio is larger than unity. The particle-laden flow development of an initially moderately rotated rectangle is qualitatively and quantitatively comparable to the dispersion of an initially triangular cloud.

Keywords: dispersion of particles, shock wave, high-order finite-difference monotonic scheme.

UDC: 532; 533.7

Received: 09.07.2012

 English version: Journal of Applied Mechanics and Technical Physics, 2013, 54:6, 900–912

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