Coupling time constants of striated and copper-plated coated conductors and the potential of striation to reduce shielding-current-induced fields in pancake coils

Amemiya, Naoyuki; Tominaga, Naoki; Toyomoto, Ryuki; Nishimoto, Takuma; Sogabe, Yusuke; Yamano, Satoshi; Sakamoto, H.

doi:10.1088/1361-6668/aa9d24

Cited by 33 publications

(52 citation statements)

References 54 publications

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“…Two typical electrical circuits of the pick-up coil method [132] and the lock-in amplifier technique [54] are presented in Figure 7. The pick-up coil method is often applied to measure the magnetization loss of superconducting samples [133][134][135][136]. The measurement system is usually composed of the AC power supply, AC electromagnet, isolation amplifier, pick-up coil, compensation circuit, compensation coil, cryostat, as well as data acquisition and processing parts, as shown in Figure 7a.…”

Section: Electric Methodsmentioning

confidence: 99%

Alternating Current Loss of Superconductors Applied to Superconducting Electrical Machines

Zhang¹,

Wen²,

Grilli

et al. 2021

Energies

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Superconductor technology has recently attracted increasing attention in power-generation- and electrical-propulsion-related domains, as it provides a solution to the limited power density seen by the core component, electrical machines. Superconducting machines, characterized by both high power density and high efficiency, can effectively reduce the size and mass compared to conventional machine designs. This opens the way to large-scale purely electrical applications, e.g., all-electrical aircrafts. The alternating current (AC) loss of superconductors caused by time-varying transport currents or magnetic fields (or both) has impaired the efficiency and reliability of superconducting machines, bringing severe challenges to the cryogenic systems, too. Although much research has been conducted in terms of the qualitative and quantitative analysis of AC loss and its reduction methods, AC loss remains a crucial problem for the design of highly efficient superconducting machines, especially for those operating at high speeds for future aviation. Given that a critical review on the research advancement regarding the AC loss of superconductors has not been reported during the last dozen years, especially combined with electrical machines, this paper aims to clarify its research status and provide a useful reference for researchers working on superconducting machines. The adopted superconducting materials, analytical formulae, modelling methods, measurement approaches, as well as reduction techniques for AC loss of low-temperature superconductors (LTSs) and high-temperature superconductors (HTSs) in both low- and high-frequency fields have been systematically analyzed and summarized. Based on the authors’ previous research on the AC loss characteristics of HTS coated conductors (CCs), stacks, and coils at high frequencies, the challenges for the existing AC loss quantification methods have been elucidated, and multiple suggestions with respect to the AC loss reduction in superconducting machines have been put forward. This article systematically reviews the qualitative and quantitative analysis methods of AC loss as well as its reduction techniques in superconductors applied to electrical machines for the first time. It is believed to help deepen the understanding of AC loss and deliver a helpful guideline for the future development of superconducting machines and applied superconductivity.

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Section: Electric Methodsmentioning

confidence: 99%

Alternating Current Loss of Superconductors Applied to Superconducting Electrical Machines

Zhang¹,

Wen²,

Grilli

et al. 2021

Energies

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“…Here, we model a thermal stabilizer such as copper on top of the SC filaments by means of a finite-resistivity conductor as in Refs. [9]- [11]. Fig.…”

Section: Model Of Multi-filament Helicalmentioning

confidence: 98%

“…We assume that the coupling current between the SC filaments flows uniformly through the thermal stabilizing layer. The stabilizer information (e.g., conductivity, thickness, and effective length responsible for the transverse conductance) can be incorporated via the transverse conductivity (resistivity) σ n = 1/ρ n as discussed in Section III, thereby reducing a three-dimensional model to a two-dimensional model [9]. Here, we model a thermal stabilizer such as copper on top of the SC filaments by means of a finite-resistivity conductor as in Refs.…”

Section: Model Of Multi-filament Helicalmentioning

confidence: 99%

Round-Core-Radius-Dependent Electromagnetic Coupling of Multifilament Helical Superconducting Tapes in a Swept Magnetic Field

Higashi,

Mawatari

2021

Preprint

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With the excitation and demagnetization of a magnet for magnetic resonance imaging in mind, we theoretically and numerically investigated electromagnetic coupling-especially its dependence on the round-core radius R-of multi-filament helically wound superconducting tapes under steady-state conditions in a constantly ramped magnetic field. We found that even in a rapidly ramped magnetic field, the electromagnetic coupling can be suppressed by reducing R to close to the tape width. We also clarified that the coupling sweep rate at which the electromagnetic coupling starts scales as R −2 , showing that the dependence on R reflects the penetration of magnetic flux from the edges of the tape. Even when the round core is as narrow as the tape width, the behavior is considered to be similar to the electromagnetic response of a flat tape rather than that of a tubular wire.

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“…As an example, the peak magnetization normalized to the wire volume of a CORC R wire at 4.2 K [175] is a factor of five higher than that of a Nb 3 Sn Rutherford cable measured at 1.9 K [176]. Tape striation is effective to reduce the magnetization in REBCO tapes [86,173,177,178], although it may increase the conductor cost/performance ratio. Compensation from the magnet aspect is another effective approach that should be explored [67,179,180].…”

Section: What Is the Field Quality Of Rebco Accelerator Magnets?mentioning

confidence: 99%

“…An automated winding machine was developed to wind coils in complex 3D shapes using single tapes [81,82]. Detailed experimental and simulation studies have been performed to understand the current distribution and its impact on the spatial and temporal field quality critical for accelerator magnet applications [83][84][85][86].…”

mentioning

confidence: 99%

Dipole Magnets above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors

2019

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To enable the physics research that continues to deepen our understanding of the Universe, future circular colliders will require a critical and unique instrument—magnets that can generate a dipole field of 20 T and above. However, today’s maturing magnet technology for low-temperature superconductors (Nb-Ti and Nb 3 Sn) can lead to a maximum dipole field of around 16 T. High-temperature superconductors such as REBCO can, in principle, generate higher dipole fields but significant challenges exist for both conductor and magnet technology. To address these challenges, several critical research needs, including direct needs on instrumentation and measurements, are identified to push for the maximum dipole fields a REBCO accelerator magnet can generate. We discuss the research needs by reviewing the current results and outlining the perspectives for future technology development, followed by a brief update on the status of the technology development at Lawrence Berkeley National Laboratory. We present a roadmap for the next decade to develop 20 T-class REBCO accelerator magnets as an enabling instrument for future energy-frontier accelerator complex.

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Coupling time constants of striated and copper-plated coated conductors and the potential of striation to reduce shielding-current-induced fields in pancake coils

Cited by 33 publications

References 54 publications

Alternating Current Loss of Superconductors Applied to Superconducting Electrical Machines

Alternating Current Loss of Superconductors Applied to Superconducting Electrical Machines

Round-Core-Radius-Dependent Electromagnetic Coupling of Multifilament Helical Superconducting Tapes in a Swept Magnetic Field

Dipole Magnets above 20 Tesla: Research Needs for a Path via High-Temperature Superconducting REBCO Conductors

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