Sage Journals: Discover world-class research

Abstract

Due to the pressure gradient increasing downstream, the boundary layer separation phenomena may occur on the divergent channel flow wall. Still, several methods have been applied to control or postponed the separation. Exerting a magnetic field on the fluid flow is one solution. In the present research, we aim to investigate the impact of magnetic fields on the separation location in a divergent channel numerically. Hence, the finite volume method using the OpenFOAM CFD toolbox is employed, and a code for 2-D divergent channel flow under a non-uniform magnetic field is developed. The obtained results have been validated in comparison with previous studies. The results are presented for a test case of the channel with divergence half-angle equals 2.5°, 30 cm length, and 2 cm inlet height. It is demonstrated when Ha increases from 0 to 2, the separation points for liquid lithium fluid flow with Re = 208.33 are postponed from 12.93 cm to 23.18 cm. Moreover, it is shown that the separation phenomena disappear entirely for the Ha value of more than 3.

Keywords

CFD magnetohydrodynamics non-uniform magnetic field OpenFOAM separation point

Get full access to this article

View all access options for this article.

References

Chen

Meng

Feng

, et al. Effect of electromagnetic coupling on MHD flow in the manifold of fusion liquid metal blanket. Fusion Eng Des 2014; 89: 1406–1410.

Abbasi

Ganji

Rahni

MT.

MHD flow in a channel using new combination of order of magnitude technique and HPM. Tehnički Vjesnik 2014; 21: 317–321.

Al-Habahbeh

Al-Saqqa

Safi

, et al. Review of magnetohydrodynamic pump applications. Alexandria Eng J 2016; 55: 1347–1358.

Jamei

Khazayinejad

Ganji

DD.

New results for boundary layer flow and convection heat transfer over a flat plate by using the homotopy perturbation method. Walailak J Sci Technol 2014; 11: 325–340.

Taheri

Abbasi

Jamei

MK.

An integral method for the boundary layer of MHD non-Newtonian power-law fluid in the entrance region of channels. J Braz Soc Mech Sci Eng 2017; 39: 4177–4189.

Taheri

Abbasi

Khaki Jamei

Application of an artificial neural network to predict the entrance length of three-dimensional magnetohydrodynamics channel flow. Eur Phys J Plus 2019; 134: 471.

Javanmard

Taheri

Askari

, et al. Third-grade non-Newtonian fluid flow and heat transfer in two coaxial pipes with a variable radius ratio with magnetic field. HFF 2020; 31: 959–981.

Mohebujjaman

Efficient numerical methods for magnetohydrodynamic flow. Dissertation, Clemson University, 2017.

Chen

Zhou

Yang

, et al. Magnetohydrodynamic experimental design and program for chinese liquid metal LiPb experimental loop DRAGON-IV. Fusion Eng Des 2010; 85: 1742–1746.

10.

Picologlou

Reed

Experimental investigation of 3-D MHD flows at high Hartmann number and interaction parameter. In: Lielpeteris J and Moreau R (eds) Liquid metal magnetohydrodynamics. Berlin, Germany: Springer, 1989, pp.71–77.

11.

Jeffery

GL.

The two-dimensional steady motion of a viscous fluid. Lond Edinb Dubl Phil Mag J Sci 1915; 29: 455–465.

12.

Hamel

Spiralformige bewegungen zaher flussigkeiten. Jahresbericht Der Deutschen Mathematiker-Vereinigung 1917; 25: 34–60.

13.

Axford

The magnetohydrodynamic Jeffrey–Hamel problem for a weakly conducting fluid. Q J Mechanics Appl Math 1961; 14: 335–351.

14.

Dennis

Dulikravich

GS.

Optimization of magneto-hydrodynamic control of diffuser flows using micro-genetic algorithms and least-squares finite elements. Finite Elem Anal Des 2001; 37: 349–363.

15.

Matsuo

Ishikawa

Umoto

Numerical analysis of bifurcation phenomena in supersonic MHD generator with supersonic diffuser. Energy Convers Manage 1994; 35: 507–516.

16.

Zhang

K-P

Ding

G-H

Tian

Z-Y

, et al. Numerical simulation of magnetohydrodynamic (MHD) control on 2D diffuser’s flow field. J Natl Univ Def Technol 2009; 9.

17.

Bararnia

Ganji

, et al. Numerical and analytical approaches to MHD Jeffery–Hamel flow in a porous channel. Int J Numer Methods Heat Fluid Flow 2012; 22: 491–502.

18.

Moghimi

Domairry

Soleimani

, et al. Application of homotopy analysis method to solve MHD Jeffery–Hamel flows in non-parallel walls. Adv Eng Software 2011; 42: 108–113.

19.

Moghimi

Ganji

Bararnia

, et al. Homotopy perturbation method for nonlinear MHD Jeffery–Hamel problem. Comput Math Appl 2011; 61: 2213–2216.

20.

Bobashev

Erofeev

Lapushkina

, et al. Effect of MHD-interaction in various parts of diffuser on inlet shocks: Experiment. In: AIAA/AAAF 11th International Space Planes and Hypersonic Systems and Technologies Conference, Orleans, France, 29–4 October 2002, p.5183.

21.

Murakami

Okuno

Experiment and simulation of MHD power generation using convexly divergent channel. In: 42nd AIAA plasmadynamics and lasers conference in conjunction with the 18th international conference on MHD Energy Conversion (ICMHD), 2013, p.3287.

22.

Yiwen

Yinghong

Haoyu

, et al. Preliminary experimental investigation on MHD power generation using seeded supersonic argon flow as working fluid. Chin J Aeronaut 2011; 24: 701–708.

23.

Sadeghy

Khabazi

Taghavi

S-M.

Magnetohydrodynamic (MHD) flows of viscoelastic fluids in converging/diverging channels. Int J Eng Sci 2007; 45: 923–938.

24.

Makinde

Effect of arbitrary magnetic reynolds number on MHD flows in convergent–divergent channels. Int J Numer Methods Heat Fluid Flow 2008; 18: 697–707.

25.

Ahmad

Ilyas

Bilal

Numerical solution for nonlinear MHD Jeffery–Hamel blood flow problem through neural networks optimized techniques. J Appl Environ Biol Sci 2014; 4: 33–43.

26.

Xisto

Páscoa

Oliveira

, et al. Implementation of a 3D compressible MHD solver able to model transonic flows. In: Proc ECCOMAS CFD Lisbon, Portugal, 14–17 June 2010, Citeseer.

27.

de Les Valls

Batet

OpenFOAM capabilities for MHD simulation under nuclear fusion technology conditions. In: OpenFOAM workshop Milan, Italy, 10–11 July 2008, pp.10–11.

28.

Mistrangelo

Bühler

Development of a numerical tool to simulate magnetohydrodynamic interactions of liquid metals with strong applied magnetic fields. Fusion Sci Technol 2011; 60: 798–803.

29.

Moghimi

Abbasi

Jamei

, et al. Effect of non-uniform magnetic field on non-newtonian fluid separation in a diffuser. Int J Eng 2020; 33: 1354–1363.

30.

Moghimi

Abbasi

Jamei

, et al. Boundary-layer separation in circular diffuser flows in the presence of an external non-uniform magnetic field. Mech Sci 2020; 11: 39–48.

31.

Roidt

Cess

An approximate analysis of laminar magnetohydrodynamic flow in the entrance region of a flat duct. J Appl Mech 1962; 29: 171–176.

32.

Davison

HW.

Compilation of thermophysical properties of liquid lithium. Washington, DC: National Aeronautics and Space Administration, 1968.

33.

Lee

Kim

HR.

Numerical analysis of the electromagnetic force for design optimization of a rectangular direct current electromagnetic pump. Nucl Eng Technol 2018; 50: 869–876.

34.

Okita

Matsuda

Yamaoka

, et al. Study on measurement of the flow velocity of liquid lithium jet using MHD effect for IFMIF. Fusion Eng Des 2018; 136: 178–182.

35.

Zinkle

Summary of physical properties for lithium, Pb-17Li, and (LiF) n• BeF2 coolants. In: APEX study meeting Albuquerque, New Mexico, United States, July 27–28 1998, pp.1–8. Sandia National Lab.

36.

Taheri

Abbasi

Jamei

MK.

Using artificial neural network for computing the development length of MHD channel flows. Mech Res Commun 2019; 99: 8–14.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

2.42 MB

0.00 MB

Evaluation of separation point in a divergent channel in the presence of non-uniform magnetic field

Abstract

Keywords

Get full access to this article

References

Supplementary Material