Abstract
Direct numerical simulations and linear stability analysis are carried out to study mixed convection in a horizontal duct with constant-rate heating applied at the bottom and an imposed transverse horizontal magnetic field. A two-dimensional approximation corresponding to the asymptotic limit of a very strong magnetic field effect is validated and applied, together with full three-dimensional analysis, to investigate the flow's behaviour in the previously unexplored range of control parameters corresponding to typical conditions of a liquid metal blanket of a nuclear fusion reactor (Hartmann numbers up to $10^4$ and Grashof numbers up to $10^{10}$ ). It is found that the instability to quasi-two-dimensional rolls parallel to the magnetic field discovered at smaller Hartmann and Grashof numbers in earlier studies also occurs in this parameter range. Transport of the rolls by the mean flow leads to magnetoconvective temperature fluctuations of exceptionally high amplitudes. It is also demonstrated that quasi-two-dimensional structure of flows at very high Hartmann numbers does not guarantee accuracy of the classical two-dimensional approximation. The accuracy deteriorates at the highest Grashof numbers considered in the study.
Highlights
Combined convection and magnetohydrodynamic (MHD) effects dramatically change the nature of flows of electrically conducting fluids
The governing equations (2.1)–(2.3) and (2.14)–(2.16) are solved numerically using the finite difference scheme introduced by Krasnov, Zikanov & Boeck (2011), and later developed, tested and applied to high Ha flows and flows with thermal convection in numerous works including those by Krasnov, Zikanov & Boeck (2012), Zhao & Zikanov (2012), Zikanov et al (2013), Zhang & Zikanov (2014) and Gelfgat & Zikanov (2018)
Magnetoconvection in a horizontal duct flow noteworthy that γmax does not decrease with Ha at Gr = 1010
Summary
Combined convection and magnetohydrodynamic (MHD) effects dramatically change the nature of flows of electrically conducting fluids. Flows of liquid metals in fusion reactor blankets and divertors are subject to very strong effects of convection (Gr ∼ 1010−1012) and magnetic fields (Ha ∼ 104) (see, e.g. Smolentsev, Moreau & Abdou 2008; Smolentsev et al 2010). Such extreme parameters present serious obstacles to analysis, because neither laboratory experiments nor 3-D simulations of unsteady flow regimes in realistic blanket or divertor geometries can, at this moment, achieve such values. Another essential difference between our work and the work by Zhang & Zikanov (2014) is that we carry out an in-depth analysis of the accuracy of the 2-D approximation applied to quasi-2-D flows at such high Ha
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