Compressibility and Rarefaction Effects on Drag of a Spherical Particle

A review of compressibility and rarefaction effects on spherical particle drag was conducted based on existing experimental data, theoretical limits, and direct simulation Monte Carlo method results. The data indicated a nexus point with respect to effects of Mach number and Knudsen number. In particular, it was found that a single drag coefficient (of about 1.63) is obtained for all particle conditions when the particle Reynolds number is about 45, and is independent of compressibility or rarefaction effects. At lower Reynolds numbers, the drag is dominated by rarefaction, and at higher Reynolds numbers, it is dominated by compressibility. The nexus, therefore, allows construction of two separate models for these two regimes. The compression-dominated regime is obtained using a modification of the Clift-Gauvin model to specifically incorporate Mach number effects. The resulting model was based on a wide range of experimental data and showed superior prediction robustness compared with previous models. For the rarefaction-dominated regime, the present model was constructed to directly integrate the theoretical creeping flow limits, including the incompressible continuum flow limit (Stokes drag), the incompressible weak rarefaction limit (Basset-Knudsen correction), and the incompressible free-molecular flow limit (Epstein theory). Empirical correlations are used to extend this model to finite particle Reynolds numbers within the rarefaction-dominated regime.

[1]  G. G. Stokes On the Effect of the Internal Friction of Fluids on the Motion of Pendulums , 2009 .

[2]  A. B. Basset On the Motion of a Sphere in a Viscous Liquid , 1887 .

[3]  Philip T. Metzger,et al.  Photogrammetry and ballistic analysis of a high-flying projectile in the STS-124 space shuttle launch , 2010 .

[4]  Robert A. Millikan,et al.  The Isolation of an Ion, a Precision Measurement of its Charge, and the Correction of Stokes's Law , 1911 .

[5]  F. Dullien,et al.  The flow of rarefied gases , 1962 .

[6]  E. Davis,et al.  Measurement of the thermophoretic force by electrodynamic levitation : microspheres in air , 1995 .

[7]  A. B. Bailey,et al.  Sphere Drag Coefficients for a Broad Range of Mach and Reynolds Numbers , 1972 .

[8]  C. B. Henderson,et al.  Drag Coefficients of Spheres in Continuum and Rarefied Flows , 1976 .

[9]  K. Schmitt Untersuchungen an Schwebstoffteilchen im Temperaturfeld , 1959 .

[10]  Jackson R Stalder,et al.  Theoretical Aerodynamic Characteristics of Bodies in a Free-Molecule-Flow Field , 1951 .

[11]  R. Clift,et al.  Bubbles, Drops, and Particles , 1978 .

[12]  J. Brock,et al.  The thermal force on spherical sodium chloride aerosols , 1965 .

[13]  M. V. Dyke,et al.  An Album of Fluid Motion , 1982 .

[14]  S. Loyalka Thermophoretic force on a single particle. I : Numerical solution of the linearized Boltzmann equation , 1992 .

[15]  Robert A. Millikan,et al.  Coefficients of Slip in Gases and the Law of Reflection of Molecules from the Surfaces of Solids and Liquids , 1923 .

[16]  D. Levin,et al.  Kinetic model for simulation of aerosol droplets in high-temperature environments , 2004 .

[17]  L. Schiller Uber die Grundlegenden Berechnungen bei der Schwerkraftaufbereitung , 1933 .

[18]  D. J. Carlson,et al.  Particle drag and heat transfer in rocket nozzles , 1964 .

[19]  G. I. Mishin,et al.  EXPERIMENTAL INVESTIGATION OF THE FLIGHT OF A SPHERE IN WEAKLY IONIZED AIR , 1997 .

[20]  F. Zheng Thermophoresis of spherical and non-spherical particles: a review of theories and experiments. , 2002, Advances in colloid and interface science.

[21]  Scaling Parameters In Rarefied Flow And the Breakdown Of The Navier-Stokes Equations , 2006 .

[22]  R. Schefer,et al.  Thermophoresis of particles in a heated boundary layer , 1980, Journal of Fluid Mechanics.

[23]  Rainald Löhner,et al.  Unstructured adaptive remeshing finite element method for dusty shock flow , 1992 .

[24]  R. Cadle,et al.  THERMAL FORCES ON AEROSOL PARTICLES1 , 1961 .

[25]  A. Haselbacher,et al.  Modeling of the unsteady force for shock–particle interaction , 2009 .

[26]  Khaleel R. A. Khasawneh,et al.  Collisionless Gas Flows over a Cylindrical or Spherical Object , 2009 .

[27]  Peter P. Wegener,et al.  Wind tunnel measurements of sphere drag at supersonic speeds and low Reynolds numbers , 1961 .

[28]  C. T. Crowe,et al.  Drag coefficient of particles in a rocket nozzle. , 1967 .

[29]  Warren F. Phillips,et al.  Drag on a small sphere moving through a gas , 1975 .

[30]  Kyoji Yamamoto,et al.  Thermophoresis of a spherical particle in a rarefied gas of a transition regime , 1988 .

[31]  C. Crowe,et al.  DRAG COEFFICIENT FOR PARTICLES IN RAREFIED, LOW MACH–NUMBER FLOWS , 1972 .

[32]  James R. Brock,et al.  On the theory of thermal forces acting on aerosol particles , 1962 .

[33]  H. Schlichting Boundary Layer Theory , 1955 .

[34]  W. E. Ranz,et al.  THERMAL FORCE ON AN AEROSOL PARTICLE IN A TEMPERATURE GRADIENT. Technical Report No. 6 , 1951 .

[35]  P. Epstein Zur Theorie des Radiometers , 1929 .