Dynamic modeling of levitation of a superconducting bulk by coupled <i>H</i>-magnetic field and arbitrary Lagrangian–Eulerian formulations

Grilli, Francesco; Morandi, Antonio; Silvestri, Federica De; Brambilla, Roberto

doi:10.1088/1361-6668/aae426

Cited by 55 publications

(33 citation statements)

References 33 publications

(52 reference statements)

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“…To solve the problem of representing a moving magnet in the H -formulation formalism [49,50], we represent the field of the magnet as a sheet current J m along the boundary ∂ R . To enforce this condition, we add a weak formulation condition to the finite-element problem,…”

Section: Model Constructionmentioning

confidence: 99%

Mechanism of the High- Tc Superconducting Dynamo: Models and Experiment

et al. 2020

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High-T c superconducting (HTS) dynamos are experimentally proven devices that can produce large (more than a kiloamp) dc currents in superconducting circuits, without the thermal leak associated with copper current leads. However, these dc currents are theoretically controversial, as it is not immediately apparent why a device that is topologically identical to an ac alternator should give a dc output at all. Here, we present a finite-element model and a comparison of it with experiment that fully explain this effect. It is shown that the dc output arises naturally from Maxwell's laws when time-varying overcritical eddy currents are induced to circulate in a HTS sheet. We first show that our finite-element model replicates all of the experimental electrical behavior reported so far for these devices, including the dc output characteristics and transient electrical waveforms. Direct experimental evidence for the presence of circulating eddy currents is also obtained through measurements of the transient magnetic field profile across the HTS tape, using a linear Hall array. These results are also found to agree closely with predictions from the finite-element model. Following this experimental validation, calculated sheet current densities and the associated local electric fields are examined for a range of frequencies and net transport currents. We find that the electrical output from a HTS dynamo is governed by the competition between transport and eddy currents induced as the magnet transits across the HTS tape. The eddy currents are significantly higher (approximately 1.5 times) than the local critical current density, and hence experience a highly nonlinear local resistivity. This nonlinearity breaks the symmetry observed in a normal ohmic material, which usually requires the net transport current to vary linearly with the average electric field. The interplay between local current densities and nonlinear resistivities (which both vary in time and space) is shown to systematically give rise to the key observed parameters of experimental HTS dynamo devices: the open-circuit voltage, the internal resistance, and the short-circuit current. Finally, we identify that the spatial boundaries formed by each edge of the HTS stator tape play a vital role in determining the total dc output. This offers the potential to develop alternative designs for HTS dynamo devices, in which the internal resistance is greatly reduced and the short-circuit current is substantially increased.

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Section: Model Constructionmentioning

confidence: 99%

Mechanism of the High- Tc Superconducting Dynamo: Models and Experiment

et al. 2020

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“…where S T is the surface of all superconducting regions. Grilli et al used H-formulation and the Arbitrary Lagrangian-Eulerian formulations to model the levitation phenomena of superconducting bulks and permanent magnets with a dynamic mesh approach [121], and Zheng et al used a similar method to investigate the electromagnetic characteristics of superconducting maglev devices [122]. Ta and Gao built a 3D electromagnetic-mechanical H-formulation FEM model to study the current density, the magnetic field distribution and the Lorentz force of a Nb 3 Sn superconducting strand [123].…”

Section: Coupling With Mechanical Modelsmentioning

confidence: 99%

Overview of H-Formulation: A Versatile Tool for Modeling Electromagnetics in High-Temperature Superconductor Applications

2020

Self Cite

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This paper reviews the modeling of high-temperature superconductors (HTS) using the finiteelement method (FEM) based on the H-formulation of Maxwell's equations. This formulation has become the most popular numerical modeling method for simulating the electromagnetic behavior of HTS, especially thanks to the easiness of implementation in the commercial finite-element program COMSOL Multiphysics. Numerous studies prove that the H-formulation is able to simulate a wide scope of HTS topologies, from simple geometries such as HTS tapes and coils, to more complex HTS devices, up to large superconducting magnets. In this paper, we review the basics of the H-formulation, its evolution from 2D to 3D, its application for calculating critical currents and AC losses as well as magnetization of HTS bulks and tape stacks. We also review the use of the H-formulation for large-scale HTS applications, its use to solve multi-physics problems involving electromagnetic-thermal and electromagnetic-mechanical couplings, and its application to study the dynamic resistance of superconductors and flux pumps. INDEX TERMSReview, H-formulation, high temperature superconductor (HTS), finite-element method (FEM).

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“…Sets of dynamic equations (Newton's and Kirchhoff's equations) that provide theory to the system are given by the following set of equations using equation (4) we have the equation of mechanical system and the differential equation of the circuit.…”

Section: ⃗ ⃗mentioning

confidence: 99%

“…A current flow through the wound coils of the electromagnet generating a magnetic field, being that the ferromagnetic core provides a path of reluctance in which the magnetic field is concentrated which induces an attractive force on the object to be levitated. Now, if we understand the theory of Superconductivity [4], we know that cooling an object at sufficiently low temperatures causes a distance to be separated from its initial base by positioning itself at a height that we can call a gap, until the temperature again decays. There is levitation by repulsion and suspension, in both cases a study of field forces must be performed, because positioning the object at the midpoint that will be the equilibrium-stable point to levitate, will depend a lot on the circuit, the coils and the distance between them, how to calibrate until the objective is achieved.…”

Section: Introductionmentioning

confidence: 99%

Study and Design of a Magnetic Levitator System

Román-Gonzalez¹,

Meneses-Claudio²,

Santos³

2019

IJACSA

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Magnetic levitation is one of the mechanisms that is at the forefront of technology. It is used in its most basic form in educational teaching, where the principles of physics converge that have as their principle electromagnetism and the fields created by existing poles that repel according to a quantity of initial current, giving instructive ideas of how the theoretical formulas work, giving life to a practical visual system. The current use on a large scale are the Maglev trains of Japan or superconductivity, being the realization of the quantum effects visualized at the moment of cooling the sample. The electronic circuit tends to be stable because, when using a high-power current, a Triac is needed to compensate the electrical flow provided by the operational amplifier and, therefore, stabilize with the photodiode when activated with the Led diode. Our purpose is to create a circuit that identifies the values of the electronic components that allow reaching equilibrium, with input and output variables that indicate the position and height of the object to be levitated.

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Dynamic modeling of levitation of a superconducting bulk by coupled H-magnetic field and arbitrary Lagrangian–Eulerian formulations

Cited by 55 publications

References 33 publications

Mechanism of the High- Tc Superconducting Dynamo: Models and Experiment

Mechanism of the High- Tc Superconducting Dynamo: Models and Experiment

Overview of H-Formulation: A Versatile Tool for Modeling Electromagnetics in High-Temperature Superconductor Applications

Study and Design of a Magnetic Levitator System

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