Electromagnetic Simulation of No-Insulation Coils Using H – $\phi$ Thin Shell Approximation

Schnaubelt, Erik; Woźniak, Mariusz; Schöps, Sebastian; Verweij, Arjan

doi:10.1109/tasc.2023.3258905

Cited by 7 publications

(14 citation statements)

References 35 publications

(57 reference statements)

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“…magnetodynamic simulations [22], and coupled magnetothermal simulations [24]. With the thin-shell approximation, the radial currents flowing across contact layers are also captured, and the results are in good agreement with simulations that use 3D contact layers [22].…”

Section: • Local Degradations Of Critical Current (Local Defects) Alongmentioning

confidence: 62%

“…FiQuS/Pancake3D is capable of conducting both magnetodynamic and coupled magneto-thermal simulations. For magnetodynamics, it uses an ⃗ H − ϕ formulation in the whole computational domain, Ω, with details in [22]. This formulation is an efficient and robust choice for systems of HTS without ferromagnetic materials [23].…”

Section: • Local Degradations Of Critical Current (Local Defects) Alongmentioning

confidence: 99%

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An open-source 3D FE quench simulation tool for no-insulation HTS pancake coils

Atalay,

Schnaubelt,

Wozniak

et al. 2024

Supercond. Sci. Technol.

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A new module, Pancake3D, of the open-source Finite Element Quench Simulator (FiQuS) has been developed in order to perform transient simulations of no-insulation (NI) high-temperature superconducting (HTS) pancake coils in 3-dimensions. FiQuS/Pancake3D can perform magnetodynamic or coupled magneto-thermal simulations. Thanks to the use of thin shell approximations, an H-Φ formulation, and anisotropic homogenization techniques, each turn can be resolved on the mesh level in an efficient and robust manner. FiQuS/Pancake3D relies on pre-formulated finite-element (FE) formulations and numerical approaches that are programmatically adjusted based on a text input file. In this paper, the functionalities and capabilities of FiQuS/Pancake3D are presented. The challenges of FE simulation of NI coils and how FiQuS/Pancake3D addresses them are explained. To highlight the functionalities, the results of a magneto-thermal analysis of a double pancake coil with 40 turns per pancake with local degradation of the critical current density are conducted and discussed. Furthermore, a parameter sweep of the size of this local degradation is presented. All the FiQuS input files for reproducing the simulations are provided.

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Section: • Local Degradations Of Critical Current (Local Defects) Alongmentioning

confidence: 62%

Section: • Local Degradations Of Critical Current (Local Defects) Alongmentioning

confidence: 99%

An open-source 3D FE quench simulation tool for no-insulation HTS pancake coils

Atalay,

Schnaubelt,

Wozniak

et al. 2024

Supercond. Sci. Technol.

Self Cite

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“…For finite-element method (FEM) models, Zhao et al [52] and Wang et al [53] proposed 3D models that built all the distinct HTS tapes including the specific turn-to-turn-contact and superconducting layers. Schnaubelt et al [54] built an NI HTS coil model based on the H−ϕ formulation with the turn-to-turn contact layers modeled as the shell elements. Mataira et al [55][56][57] proposed a method that models the NI coil as a homogeneous bulk set with an anisotropic resistivity; this method has been used and verified by quite a few groups in the world [58][59][60][61][62][63][64][65].…”

Section: Introductionmentioning

confidence: 99%

Study of the demagnetization behavior of no-insulation persistent-current mode HTS coils under external AC fields by 3D FEM simulation

Zhong,

Wu,

et al. 2024

Supercond. Sci. Technol.

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The no-insulation (NI) winding technique is promising to be applied in the persistent-current mode (PCM) operation of high-temperature superconducting (HTS) coils to provide those advantages. To apply the NI PCM coil, its demagnetization behaviour (i.e., decay of persistent DC current) by external AC field, which occurs in maglev trains, electric machines, and other dynamic magnet systems, is essential to be understood. For this purpose, a 3D FEM model, capturing the full electromagnetic properties of NI HTS coils, is established. This work has studied three kinds of AC fields, observing the impact of turn-to-turn contact resistivity on demagnetization rates, which is attributed to current distribution modulations. Under transverse AC field, the lower contact resistivity attracts more transport current to flow in the radial pathway to bypass the ‘dynamic resistance’ generated in the superconductor, leading to slower demagnetization. Under axial AC field, the demagnetization rate exhibits a non-monotonic relation with the contact resistivity: (1) the initial decrease of contact resistivity leads to concentration of induced AC current on the outer turns, which accelerates the demagnetization; (2) the further decrease of contact resistivity makes the current smartly redistribute to avoid to flow through the loss-concentrated outer turns, thus slowing down the demagnetization. Under the rotating DC field, a hybrid of the transverse and axial fields, the impact of contact resistivity on the demagnetization rate exhibits combined characteristics of the transverse and axial components. Besides, quantitative prediction on the demagnetization rate of NI PCM coil under external AC field is instructive for practical designs and operations, which is tried by this 3D FEM model, and a comparison with experimental result is conducted.

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“…First, a thermal TSA to represent thin insulation layers by considering the heat equation was introduced in [14]. Second, a magnetodynamic ⃗ H − ϕ TSA was used to study the charge and discharge of NI coils in [16]. By replacing T2TCL volumes with surfaces, no volumetric mesh of the thin layer is required.…”

mentioning

confidence: 99%

“…By replacing T2TCL volumes with surfaces, no volumetric mesh of the thin layer is required. This work proposes to combine the thermal TSA of [14] and the magnetodynamic TSA of [16] to model T2TCL with magneto-thermal T2TCL taking into account the coupling via i) non-linear material relations and ii) Joule losses.…”

mentioning

confidence: 99%

Magneto-Thermal Thin Shell Approximation for 3D Finite Element Analysis of No-Insulation Coils

Schnaubelt,

Atalay,

Wozniak

et al. 2024

IEEE Trans. Appl. Supercond.

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For finite element (FE) analysis of no-insulation (NI) high-temperature superconducting (HTS) pancake coils, the high aspect ratio of the turn-to-turn contact layer (T2TCL) leads to meshing difficulties which result in either poor quality mesh elements resulting in a decrease of the solution accuracy or a high number of degrees of freedom. We proposed to mitigate this issue by collapsing the T2TCL volume into a surface and using a so-called thin shell approximation (TSA). Previously, two TSA have been introduced, one to solve the heat equation and the other for an ⃗ H − ϕ magnetodynamic formulation. In this work, we propose to combine the magnetodynamic and thermal TSA to create a coupled magneto-thermal TSA for three-dimensional FE analysis. Particular attention is paid to the detailed derivation of the coupling terms. In the context of NI HTS pancake coils, the TSA represents the electric and thermal contact resistance of the T2TCL. For the HTS coated conductor (CC) itself, an anisotropic homogenization is used which represents its multi-layered structure. In axial and azimuthal direction, it resolves the current sharing between the HTS and other layers of the CC. The coupled TSA formulation is verified against a reference model with volumetric T2TCL. The coupled TSA is shown to significantly reduce the solution time as well as the manual effort required for high-quality meshes of the T2TCL. The implementation is open-source and a reference implementation is made publicly available. IndexTerms-no-insulation coil, thin shell approximation, magneto-thermal analysis, ⃗ H − ϕ formulation, finite elements I. INTRODUCTION No-insulation (NI) pancake coils [1] have no turn-to-turn electrical insulation and are popular due to their high thermal stability [2] resulting from a possibility for currents to bypass local normal zones [3]-[5]. Despite this, quenches are still possible in NI coils [6]-[11]. To this end, quench detection and protection of NI coils require appropriate modeling and analysis methods.

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Electromagnetic Simulation of No-Insulation Coils Using H – $\phi$ Thin Shell Approximation

Cited by 7 publications

References 35 publications

An open-source 3D FE quench simulation tool for no-insulation HTS pancake coils

An open-source 3D FE quench simulation tool for no-insulation HTS pancake coils

Study of the demagnetization behavior of no-insulation persistent-current mode HTS coils under external AC fields by 3D FEM simulation

Magneto-Thermal Thin Shell Approximation for 3D Finite Element Analysis of No-Insulation Coils

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