Influence of Magnetic Force on the Flow Stability in a Rectangular duct
Rahman Anisur, Wenqia Xu, Kunhang Li, Hua-Shu Dou, Boo Cheong Khoo,, Jie Mao

TL;DR
This study investigates how magnetic forces influence flow stability in a rectangular duct using simulations and energy gradient theory, revealing that increased magnetic force enhances stability and shifts potential instability regions.
Contribution
It applies energy gradient theory to magnetohydrodynamic flow in a rectangular duct, demonstrating magnetic control of flow stability with varying Hartmann numbers.
Findings
Higher Hartmann numbers decrease flow instability.
Maximum energy gradient K shifts towards the duct wall with increasing Ha.
Magnetic force modulation can control flow stability.
Abstract
The stability of the flow under the magnetic force is one of the classical problems in fluid mechanics. In this paper, the flow in a rectangular duct with different Hartmann (Ha) number is simulated. The finite volume method and the SIMPLE algorithm are used to solve a system of equations and the energy gradient theory is then used to study the (associated) stability of magnetohydrodynamics (MHD). The flow stability of MHD flow for different Hartmann (Ha) number, from Ha=1 to 40, at the fixed Reynolds number, Re=190 are investigated. The simulation is validated firstly against the simulation in literature. The results show that, with the increasing Ha number, the centerline velocity of the rectangular duct with MHD flow decreases and the absolute value of the gradient of total mechanical energy along the streamwise direction increases. The maximum of K appears near the wall in both…
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Taxonomy
TopicsFluid Dynamics and Turbulent Flows · Nanofluid Flow and Heat Transfer · Heat Transfer Mechanisms
