Interaction of a small permanent magnet with a liquid metal duct flow

Heinicke, Christiane; Tympel, Saskia; Pulugundla, Gautam; Rahneberg, Ilko; Boeck, Thomas; Thess, André

doi:10.1063/1.4770155

Cited by 16 publications

(17 citation statements)

References 33 publications

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“…The aim of this article is to investigate the structure formation and the locally resolved Lorentz force fields in a liquid metal duct flow in the presence of a magnetic point dipole field. The flow and magnetic field configurations are similar to recent laboratory experiments on LFV using liquid InGaSn alloy at room temperature 24 . We conduct three-dimensional DNS based on the quasi-static approximation of the induction equation.…”

Section: Introductionsupporting

confidence: 82%

Laminar and transitional liquid metal duct flow near a magnetic point dipole

2013

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The flow transformation and the generation of vortex structures by a strong magnetic dipole field in a liquid metal duct flow is studied by means of three-dimensional direct numerical simulations. The dipole is considered as the paradigm for a magnetic obstacle which will deviate the streamlines due to Lorentz forces acting on the fluid elements. The duct is of square cross-section. The dipole is located above the top wall and is centred in spanwise direction. Our model uses the quasistatic approximation which is applicable in the limit of small magnetic Reynolds numbers. The analysis covers the stationary flow regime at small hydrodynamic Reynolds numbers Re as well as the transitional time-dependent regime at higher values which may generate a turbulent flow in the wake of the magnetic obstacle. We present a systematic study of these two basic flow regimes and their dependence on Re and on the Hartmann number Ha, a measure of the strength of the magnetic dipole field. Furthermore, three orientations of the dipole are compared: streamwise-, spanwise-and wall-normaloriented dipole axes. The most efficient generation of turbulence at a fixed distance above the duct follows for the spanwise orientation, which is caused by a certain configuration of Hartmann layers and reversed flow at the top plate. The enstrophy in the turbulent wake grows linearly with Ha which is connected with a dominance of the wall-normal derivative of the streamwise velocity.

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Section: Introductionsupporting

confidence: 82%

Laminar and transitional liquid metal duct flow near a magnetic point dipole

2013

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“…The volume fluxV of the cooling water is measured using an axial turbine flow sensor. The LLFV measurement system [17] consists of a cubic permanent magnet of side length 5 mm, which is placed on a parallel spring. The deflection of the spring through the force acting on the magnet is measured by a laser interferometer.…”

Section: Methodsmentioning

confidence: 99%

“…The forces are directed opposite to the flow and act as a brake on the fluid motion. At the same time, due to Newton's Third Law, a force in the range of micro-to millinewton acts on the permanent magnet which can be measured by precision methods [17]. It has the same * Corresponding author: till.zuerner@tu-ilmenau.de magnitude as the sum of all Lorentz forces in the liquid, but is directed in the opposite direction -the magnet is in effect dragged along with the flow.…”

Section: Introductionmentioning

confidence: 99%

Local Lorentz force and ultrasound Doppler velocimetry in a vertical convection liquid metal flow

et al. 2017

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We report velocity measurements in a vertical turbulent convection flow cell that is filled with the eutectic liquid metal alloy gallium-indium-tin by the use of local Lorentz force velocimetry (LLFV) and ultrasound Doppler velocimetry (UDV). We demonstrate the applicability of LLFV for a thermal convection flow and reproduce a linear dependence of the measured force in the range of micronewtons on the local flow velocity magnitude. Furthermore, the presented experiment is used to explore scaling laws of the global turbulent transport of heat and momentum in this low-Prandtl-number convection flow. Our results are found to be consistent with theoretical predictions and recent direct numerical simulations.

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“…So far, the L2F2 has been used for duct flow experiments only [10]. In this paper, we will present the application of the L2F2 to a liquid metal flow in a closed cylindrical container at room temperature.…”

Section: Introductionmentioning

confidence: 99%

Contact-free measurement of the flow field of a liquid metal inside a closed container

Heinicke

2014

EPJ Web of Conferences

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Abstract. The measurement of flow velocities inside metal melts is particularly challenging. Due to the high temperatures of the melts it is impossible to employ measurement techniques that require either mechanical contact with the melt or are only adaptable to translucent fluids. In the past years a number of electromagnetic techniques have been developed that allows a contact-free measurement of volume flows. One of these techniques is the so-called Lorentz Force Velocimetry (LFV) in which the metal flow is exposed to an external, permanent magnetic field. The interaction between the metal and the magnet not only leads to a force on the fluid, but also on the magnet. The force can be measured and is proportional to the velocity of the melt. Moreover, by using a small permanent magnet it is possible to resolve spatial structures inside the flow. We will demonstrate this using a model experiment that has been investigated with different reference techniques previously. The experimental setup is a cylindrical vessel filled with a eutectic alloy which is liquid at room temperature. The liquid metal can be set into motion by means of a propeller at the top of the liquid. Depending on the direction of rotation of the propeller, the flow inside the vessel takes on different states. Beside the vessel, we place a Lorentz Force Flowmeter (LFF) equipped with a small permanent magnet. By measuring the force on the magnet at different positions and different rotation speeds, we demonstrate that we can qualitatively and quantitatively reconstruct the flow field inside the vessel.

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Interaction of a small permanent magnet with a liquid metal duct flow

Cited by 16 publications

References 33 publications

Laminar and transitional liquid metal duct flow near a magnetic point dipole

Laminar and transitional liquid metal duct flow near a magnetic point dipole

Local Lorentz force and ultrasound Doppler velocimetry in a vertical convection liquid metal flow

Contact-free measurement of the flow field of a liquid metal inside a closed container

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