Files in this item

FilesDescriptionFormat

application/pdf

application/pdfTAM927-UILU ENG 1999-6002.pdf (4MB)
(no description provided)PDF

Description

Title:A fast eulerian methof for two-phase flow
Author(s):Ferry, James P.; Balachandar, S.
Subject(s):Particle Velocity
Direct Numerical Simulation
Particle Distrbution
Abstract:We propose a variant of the Eulerian method for two-phase flow that is valid for small particle response time T. For small T, the particle velocity field v(x, t) approaches a unique, equilibrium field, independent of initial conditions. A precise inequality is derived specifying how small T must be for this to occur. When it does, v(x, t) depends only on local fluid quantities (velocity and its spatial and temporal derivatives), and may be expressed as an expansion in T. We derive an expansion which generalizes those of Maxey (1987) and Druzhinin ( 1995). The first-order truncation of this expansion may be computed efficiently, so by using it to approximate v, the method avoids the need to solve additional partial differential equations, and therefore is much faster than the standard Eulerian method. Results from a direct numerical simulation of turbulent channel flow indicate that this first-order approximation of v is sufficiently accurate. Static tests performed at one time-instance show the actual velocities of particles evolved in a Lagrangian fashion are estimated well by evaluating the first-order approximation of v at the particles' positions. In particular, turbophoresis is represented accurately. Dynamic tests examine the effect of using the first-order approximation of v to evolve particles. The distribution of particles evolved in this way differs little from that of particles evolved using the standard Lagrangian method, indicating that static errors do not accumulate over time. In particular, the approximate method accurately captures preferential concentration in regions of high strain and low vorticity. Analogous results hold for bubbles. Therefore, for sufficiently small particles of any density, the first-order approximation to v is accurate, so the proposed variant of the Eulerian method is both accurate and fast.
Issue Date:2000-02
Publisher:Department of Theoretical and Applied Mechanics. College of Engineering. University of Illinois at Urbana-Champaign
Series/Report:TAM R 927
2000-6002
Genre:Technical Report
Type:Text
Language:English
URI:http://hdl.handle.net/2142/112636
ISSN:0073-5264
Sponsor:Center for Simulation of Advanced Rocket; US Departmentartment of Energy
Rights Information:Copyright 2000 Board of Trustees of the University of Illinois
Date Available in IDEALS:2021-11-04


This item appears in the following Collection(s)

  • Technical Reports - Theoretical and Applied Mechanics (TAM)
    TAM technical reports include manuscripts intended for publication, theses judged to have general interest, notes prepared for short courses, symposia compiled from outstanding undergraduate projects, and reports prepared for research-sponsoring agencies.

Item Statistics