User defined elements in ANSYS for 2D multiphysics modeling of superconducting magnets

Brouwer, Lucas; Arbelaez, Diego; Auchmann, Bernhard; Bortot, Lorenzo; Stubberud, Edvard

doi:10.1088/1361-6668/ab2e63

Cited by 9 publications

(7 citation statements)

References 23 publications

(35 reference statements)

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“…The fast transients in superconducting magnets during a quench can induce high mechanical stress, and protecting against quenching becomes more complex as the quest for higher magnetic fields intensifies [44]. The challenges require interconnected simulation models across domains, emphasizing the increasing relevance of multi-physics numerical models that link thermal, mechanical, and electromagnetic components [45]. The issue of simulating non-linear transient effects in superconducting accelerator magnets is characterized as multi-domain, multi-physics, multi-rate, and multi-scale, involving the magnet, its circuits, and the power converter controller [46].…”

Section: Multi-physics Modelmentioning

confidence: 99%

“…These domains involve multiple interconnected physical phenomena demanding a simulation infrastructure allowing model-order reduction while facilitating information exchange between different software packages. Quenches in the operation of superconducting magnets can cause damage to the surrounding infrastructure and circuitry, requiring special protection systems whose interactions with the magnet must be simulated, incorporating multi-physical properties, heat propagation equations, and mechanical models [45,47]. This modeling process, complicated by domain coupling and multiscale phenomena, necessitates using multiple simulation tools like Ansys ® and COMSOL ® in tandem to model the electromagnetic and thermal domain couplings.…”

Section: Multi-physics Modelmentioning

confidence: 99%

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Overview of Identified Challenges in the Development Process of Superconducting Accelerator Magnets

Kaeske,

Fiscarelli,

Albers

et al. 2024

Designs

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Development challenges in the domain of superconducting magnets are concentrated on technical problems in the current literature. Organizational, domain-specific challenges are often seen as secondary but must be considered with new holistic development approaches like Model-Based Systems Engineering (MBSE) becoming more popular. This work quantifies the domain challenges and gives the foundation to derive success criteria for design support in the future. A systematic literature review has been conducted to identify the overall domain challenges, and extensive interviews in the CERN technology department have been carried out to identify the development challenges on a practical level. Problems in knowledge management have been identified as a major challenge in the development process and the general literature. The paper concludes by picking up the most important challenges from the interviews and literature and puts them into the context of the authors’ knowledge of electrical magnet design.

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Section: Multi-physics Modelmentioning

confidence: 99%

Section: Multi-physics Modelmentioning

confidence: 99%

Overview of Identified Challenges in the Development Process of Superconducting Accelerator Magnets

Kaeske,

Fiscarelli,

Albers

et al. 2024

Designs

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“…Research and development work on implementing self-developed numerical methods into the finite-element method (FEM) software ANSYS is ongoing at the Paul Scherrer Institute (PSI) for the purpose of modelling and optimizing the short-period and high-field staggered-array high-temperature superconductor (HTS) bulk undulators which are highly appreciated for the construction of compact free electron lasers (FELs) [1]- [3]. The idea of developing ANSYS comes from its powerful capability for mechanical or multiphysics-coupled simulations and its parametric design language (APDL) which allows the secondary development or the user-defined element [4]. Our ambitious goal is to develop adaptive numerical algorithms which could allow the electromagnetic modelling of HTS obeying the critical state model or the flux creep model (e.g., E-J power law), but with This work is supported by European Union's Horizon2020 research and innovation program under grant agreement No.…”

Section: Introductionmentioning

confidence: 99%

Magnetization Current Simulation of High-Temperature Bulk Superconductors Using the ANSYS Iterative Algorithm Method

Zhang

Hellmann

Calvi

et al. 2021

IEEE Trans. Appl. Supercond.

Self Cite

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The A-V formulation based iterative algorithm method (IAM), developed at Paul Scherrer Institute, shows excellent performance in modelling the critical state magnetization-current in the ReBCO tape stacks after field-cooling (FC) magnetization. This paper upgrades the function of the IAM, making it realistic to take into account the widely used E-J power law, as well as to model the magnetization-current in bulk high-temperature superconductors (HTS) under a zero-field-cooling (ZFC) cycle, having both the magnetization and demagnetization stages. The simulation results obtained from the ANSYS-IAM are validated with the well-known H-formulation method for both the critical state model and the flux creep model. The computation times from using the two different numerical methods are compared and discussed. The influence factors, including the iteration steps, the initial superconductor resistivity, the ramping time and the reservation coefficient, are studied in detail.

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“…This issue did not emerge in our recent works [11], [14], since the non-conducting domains did not surround any net current in the models considered. Nonetheless, in many applications of interest, a net current is needed in the HTS domains [15]- [19].…”

Section: Introductionmentioning

confidence: 99%

COMSOL implementation of the H-$ϕ$-formulation with thin cuts for modeling superconductors with transport currents

Arsenault,

Alves,

Sirois

2021

Preprint

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Despite the acclaimed success of the magnetic field (H) formulation for modeling the electromagnetic behavior of superconductors with the finite element method, the use of vector-dependent variables in non-conducting domains leads to unnecessarily long computation times. In order to solve this issue, we have recently shown how to use a magnetic scalar potential together with the H-formulation in the COMSOL Multiphysics environment to efficiently and accurately solve for the magnetic field surrounding superconducting domains. However, from the definition of the magnetic scalar potential, the non-conducting domains must be made simply connected in order to obey Ampere's law. In this work, we use thin cuts to apply a discontinuity in φ and make the non-conducting domains simply connected. This approach is shown to be easily implementable in the COMSOL Multiphysics finite element program, already widely used by the applied superconductivity community. We simulate three different models in 2-D and 3-D using superconducting filaments and tapes, and show that the results are in very good agreement with the H-A and H-formulations. Finally, we compare the computation times between the formulations, showing that the H-φ-formulation can be up to seven times faster than the standard H-formulation in certain applications of interest.

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User defined elements in ANSYS for 2D multiphysics modeling of superconducting magnets

Cited by 9 publications

References 23 publications

Overview of Identified Challenges in the Development Process of Superconducting Accelerator Magnets

Overview of Identified Challenges in the Development Process of Superconducting Accelerator Magnets

Magnetization Current Simulation of High-Temperature Bulk Superconductors Using the ANSYS Iterative Algorithm Method

COMSOL implementation of the H-$ϕ$-formulation with thin cuts for modeling superconductors with transport currents

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