Mach Wave and Acoustical Wave Structure in Nonequilibrium Gas-Particle Flows
Author | : Joseph T. C. Liu |
Publisher | : Cambridge University Press |
Total Pages | : 78 |
Release | : 2021-10-07 |
ISBN-10 | : 9781108997799 |
ISBN-13 | : 1108997791 |
Rating | : 4/5 (99 Downloads) |
Book excerpt: In this Element, the gas-particle flow problem is formulated with momentum and thermal slip that introduces two relaxation times. Starting from acoustical propagation in a medium in equilibrium, the relaxation-wave equation in airfoil coordinates is derived though a Galilean transformation for uniform flow. Steady planar small perturbation supersonic flow is studied in detail according to Whitham's higher-order waves. The signals owing to wall boundary conditions are damped along the frozen-Mach wave, and are both damped and diffusive along an effective-intermediate Mach wave and diffusive along the equilibrium Mach wave where the bulk of the disturbance propagates. The surface pressure coefficient is obtained exactly for small-disturbance theory, but it is considerably simplified for the small particle-to-gas mass loading approximation, equivalent to a simple-wave approximation. Other relaxation-wave problems are discussed. Martian dust-storm properties in terms of gas-particle flow parameters are estimated.