Hadikhani, P., Majidi, S., Afshari, A. (2018). A preconditioned solver for sharp resolution of multiphase flows at all Mach numbers. Journal of Computational Applied Mechanics, (), -. doi: 10.22059/jcamech.2018.254180.246

Pooria Hadikhani; Sahand Majidi; Asghar Afshari. "A preconditioned solver for sharp resolution of multiphase flows at all Mach numbers". Journal of Computational Applied Mechanics, , , 2018, -. doi: 10.22059/jcamech.2018.254180.246

Hadikhani, P., Majidi, S., Afshari, A. (2018). 'A preconditioned solver for sharp resolution of multiphase flows at all Mach numbers', Journal of Computational Applied Mechanics, (), pp. -. doi: 10.22059/jcamech.2018.254180.246

Hadikhani, P., Majidi, S., Afshari, A. A preconditioned solver for sharp resolution of multiphase flows at all Mach numbers. Journal of Computational Applied Mechanics, 2018; (): -. doi: 10.22059/jcamech.2018.254180.246

A preconditioned solver for sharp resolution of multiphase flows at all Mach numbers

^{1}School of Mechanical Engineering, College of Engineering,University of Tehran,Tehran,Iran

^{2}Faculty of Mechanical and Energy Engineering, Shahid Beheshti University, A.C., Tehran, Iran

Receive Date: 15 March 2018,
Revise Date: 16 August 2018,
Accept Date: 22 August 2018

Abstract

A preconditioned five-equation two-phase model coupled with an interface sharpening technique is introduced for simulation of a wide range of multiphase flows with both high and low Mach regimes. Harten-Lax-van Leer-Contact (HLLC) Riemann solver is implemented for solving the discretized equations while tangent of hyperbola for interface capturing (THINC) interface sharpening method is applied to reduce the excessive diffusion of the method at the interface. In this work, preconditioning technique is used in a system of equations including viscous and capillary effects. Several one- and two-dimensional test cases are used to evaluate the performance and accuracy of this method. Numerical results demonstrate the efficiency of preconditioning in low Mach number flows. Comparisons between results of preconditioned and conventional system highlight the necessity of using preconditioning technique to reproduce main characteristics of low-speed flow regimes. Additionally, preconditioned systems transform to the conventional systems at high Mach number flows thus exhibiting the same level of accuracy as the standard flow solver. Therefore, the preconditioned compressible two-phase method can be used as an all-speed two-phase flow solver accounting for capillary and viscous stresses.

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