AC loss characteristics of CORC<sup>®</sup>cable with a Cu former

Terzioğlu, Rıfkı; Vojenčiak, M.; Sheng, Jie; Gömöry, Fedor; Çavuş, Türker Fedai; Belenli, I.

doi:10.1088/1361-6668/aa757d

Cited by 39 publications

(24 citation statements)

References 25 publications

(29 reference statements)

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“…With a transposition on all the tapes in each layer, the CORC cable approach is effective in reducing the coupling currents in REBCO tapes, as well as magnetization loss. This has been validated experimentally in previous studies [26][27][28][29]. To further reduce the magnetization AC loss, researchers proposed to divide single tapes into multi-filaments [30][31][32][33][34][35][36].…”

Section: Introductionmentioning

confidence: 65%

Study of the magnetization loss of CORC^® cables using a 3D T-A formulation

Wang

Zhang

Grilli

et al. 2019

Supercond. Sci. Technol.

132

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Conductor on round core (CORC) cable wound with high temperature superconductors (HTS) is an important cable concept for high current density applications. The design of CORC cable makes the understanding of its electromagnetic performance -for example its AC losses -challenging. This paper presents a thorough study for CORC cables by combining experimental and numerical methods. In particular, the paper focuses on understanding how the cable structure influences the magnetization losses and on how these can be reduced. A novelty of this paper lies in the use of a new T-A formulation, which, for the first time, is employed for 3D modelling of CORC cable with real geometry. The use of the new T-A formulation in finite element software enables the study of how the winding direction and multiple-layer structure affect the magnetization losses of CORC cables. Moreover, influence of striation in CORC cable is studied as an effective way to reduce its losses. The CORC cable with striated tapes shows a significant magnetization loss reduction at high magnetic fields, in comparison to its un-striated counterpart. At low magnetic fields, tape striation leads to a loss rise when the number of filaments is low, then the loss drops with the further increase of filaments, but this loss reduction is much weaker than that at high fields. The paper provides an efficient tool for investigating the electromagnetic behaviour of CORC cables, which can provide valuable guidance in designing CORC cables with minimized losses for high energy physics and energy conversion applications. c c par per b par per c J J J B

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Section: Introductionmentioning

confidence: 65%

Study of the magnetization loss of CORC^® cables using a 3D T-A formulation

Wang

Zhang

Grilli

et al. 2019

Supercond. Sci. Technol.

132

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“…Replotted from [36] model [51]. Terzioğlu et al studied the transport current AC loss and magnetization AC losses (frequency 36, 72 and 144 Hz) of the HTS CORC with a Cu former by experiment and H-formulation method [52].…”

Section: H-formulation For the Ac Loss In Hts Cablesmentioning

confidence: 99%

Review of the AC loss computation for HTS using H formulation

Shen

Grilli

Coombs

2020

Supercond. Sci. Technol.

200

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This paper overviews the computation of the alternating current (AC) loss in high temperature superconductors (HTS) based on the finite-element method (FEM) using H-Formulation. A great amount of studies shows that the AC loss calculation results from H-Formulation agree well with the experiment results. As one of the most reliable numerical modeling methods, H-Formulation is able to calculate the AC loss from a wide range of HTS topologies. In this paper, we review these contributions on the AC loss calculation using H-Formulation, from small-scale HTS tapes and coils, HTS cables, to large-scale HTS applications.

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“…To simulate a CORC cable, the AC losses were simulated at first by a two-dimensional model neglecting the winding of the tapes [12]. Later, an improved simulation study of the magnetization losses in CORC cables was carried out using three-dimensional models based on the H formulation [7], [13]. Simulations with three-dimensional models using the T-A formulation have also been conducted to investigate the AC losses in CORC cables, twisted stacked-tape conductor cables, and double coaxial cables with various transport currents and background magnetic fields [14].…”

Section: Introductionmentioning

confidence: 99%

Efficient Numerical Modeling of the Magnetization Loss on a Helically Wound Superconducting Tape in a Ramped Magnetic Field

Higashi

Mawatari

2020

IEEE Trans. Appl. Supercond.

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We investigate theoretically the dependence of magnetization loss of a helically wound superconducting tape on the round core radius R and the helical conductor pitch in a ramped magnetic field. Using the thin-sheet approximation, we identify the two-dimensional equation that describes Faraday's law of induction on a helical tape surface in the steady state. Based on the obtained basic equation, we simulate numerically the current streamlines and the power loss P per unit tape length on a helical tape. For R w0 (where w0 is the tape width), the simulated value of P saturates close to the loss power ∼ (2/π)P flat (where P flat is the loss power of a flat tape) for a loosely twisted tape. This is verified quantitatively by evaluating power loss analytically in the thin-filament limit of w0/R → 0. For R w0, upon thinning the round core, the helically wound tape behaves more like a cylindrical superconductor as verified by the formula in the cylinder limit of w0/R → 2π, and P decreases further from the value for a loosely twisted tape, reaching ∼ (2/π) 2 P flat .

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AC loss characteristics of CORC^®cable with a Cu former

Cited by 39 publications

References 25 publications

Study of the magnetization loss of CORC^® cables using a 3D T-A formulation

Study of the magnetization loss of CORC^® cables using a 3D T-A formulation

Review of the AC loss computation for HTS using H formulation

Efficient Numerical Modeling of the Magnetization Loss on a Helically Wound Superconducting Tape in a Ramped Magnetic Field

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AC loss characteristics of CORC®cable with a Cu former

Cited by 39 publications

References 25 publications

Study of the magnetization loss of CORC® cables using a 3D T-A formulation

Study of the magnetization loss of CORC® cables using a 3D T-A formulation

Review of the AC loss computation for HTS using H formulation

Efficient Numerical Modeling of the Magnetization Loss on a Helically Wound Superconducting Tape in a Ramped Magnetic Field

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Product

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AC loss characteristics of CORC^®cable with a Cu former

Study of the magnetization loss of CORC^® cables using a 3D T-A formulation

Study of the magnetization loss of CORC^® cables using a 3D T-A formulation