Numerical modeling of a HTS cable

Grilli, Francesco; Stavrev, S.; Dutoit, B.; Spreafico, S.

doi:10.1109/tasc.2003.812940

Cited by 11 publications

(5 citation statements)

References 8 publications

(13 reference statements)

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“…The error of this approximation is negligible for singlelayer cables. Moreover, thanks to symmetry, the cross-section in the computations can be reduced to a single circular sector [142], [143], [144]. Simulations for tapes with a ferromagnetic substrate show that its presence always increases the ac losses [145], [146].…”

Section: ) Power-transmission Cablesmentioning

confidence: 99%

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Grilli

Pardo

Stenvall

et al. 2014

IEEE Trans. Appl. Supercond.

305

272

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Numerical modeling of superconductors is widely recognized as a powerful tool for interpreting experimental results, understanding physical mechanisms and predicting the performance of high-temperature superconductor (HTS) tapes, wires and devices. This is especially true for ac loss calculation, since a sufficiently low ac loss value is imperative to make these materials attractive for commercialization. In recent years, a large variety of numerical models, based on different techniques and implementations, have been proposed by researchers around the world, with the purpose of being able to estimate ac losses in HTSs quickly and accurately. This article presents a literature review of the methods for computing ac losses in HTS tapes, wires and devices. Technical superconductors have a relatively complex geometry (filaments, which might be twisted or transposed, or layers) and consist of different materials. As a result, different loss contributions exist. In this paper, we describe the ways of computing such loss contributions, which include hysteresis losses, eddy current losses, coupling losses, and losses in ferromagnetic materials. We also provide an estimation of the losses occurring in a variety of power applications.

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Section: ) Power-transmission Cablesmentioning

confidence: 99%

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Grilli

Pardo

Stenvall

et al. 2014

IEEE Trans. Appl. Supercond.

305

272

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“…If the same number of tapes is used for all the layers, as in this investigation, the outer layers have a lower effective critical current than the inner ones, where the effects of the magnetic field are less important. The effect of the magnetic field results in a decrease of the effective critical current of the cable (as much as a 25% smaller I c , see [16]) and in an increase of the AC loss, which cannot be neglected, especially at large currents.…”

Section: Reduced Critical Current and Power Law Exponentmentioning

confidence: 99%

“…The model of the hysteretic inductances ( 4)-( 6) requires a constant critical current I c , so in order to take into account the effect of the field dependence, we have computed the average magnetic field acting on the layers by means of 2D FEM simulations (details of the implementation can be found in [16]). The uniform current distribution across the layers has been obtained using four independent current sources for injecting the transport current.…”

Section: Reduced Critical Current and Power Law Exponentmentioning

confidence: 99%

Prediction of resistive and hysteretic losses in a multi-layer high-T_csuperconducting cable

Grilli

Sjöström

2004

Supercond. Sci. Technol.

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In this work, a model of a multi-layer high-Tc superconducting (HTS) cable that computes the current distribution across layers as well as the AC loss is presented. The case of a four-layer cable is analysed, but the method developed can be applied to a cable with an arbitrary number of layers. The cable is modelled by an equivalent circuit consisting of the following elements: nonlinear resistances, linear self- and mutual inductances, as well as nonlinear, hysteretic inductances. The first element takes into account the typical current–voltage relation for superconductors, the second introduces coupling among the layers and depends on the geometrical parameters of the cable, while the third describes the hysteretic behaviour of superconductors. In the analysis presented, the geometrical dimensions of the cable are fixed, except for the pitch length and the winding orientation of the layers. These free parameters are varied in order to partition the current across the layers such that the AC loss in the superconductor is minimized. The model presented allows us to evaluate rapidly the current distribution across the different layers and to compute the corresponding AC loss. The rapidity of the computation allows us to calculate the losses for many different configurations within a reasonable time. The model has first been used for finding the pitch lengths giving an optimal current distribution across the layers and for computing the corresponding AC loss. Second, the model has been refined, taking into account the effects of the magnetic self-field which, especially at high currents, can sensibly reduce the transport capacity of the cable, in particular in the outer layers.

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“…Хотя состояние технологии ВТСП-кабелей уже сейчас позволя-ет создавать экономически выгодные линии электропередач и другие сложные технические устройства, критический сверхпро-водящий ток токонесущих текстурированных ВТСП-элементов в 100 и более раз меньше величины j c для эпитаксиальных ВТСП-пленок А/см 2 [5,11]. Поэтому поиск технологий получения высоких токонесущих характеристик для случая традиционных поликристаллических ВТСП-материалов остается сейчас не менее актуальной задачей, чем и 10 лет назад.…”

Section: природа токонесущей способности втспunclassified

“…традиционные методы получения ВТСП с применением различных способов твердофазного синтеза и термомеха-нической обработки, в том числе модифицированными ме-тодами порошковой металлургии [2,6,7]; 2. различные нетрадиционные методы получения ВТСП, по-зволившие создать эпитаксиальные сверхпроводящие пленки с высокими критическими параметрами (Т с и j c ) [3][4][5][8][9][10]. Традиционные методы изготовления ВТСП-лент позволяют по-лучать образцы с j c  (3-6)10 4 А/см 2 при Т  77 К и уже сейчас применяются для создания различных токонесущих ВТСП-кабелей, работающих при температуре жидкого азота (или азота под откачкой) [11,12]. Результаты, полученные к настоящему времени по ВТСП-кабелям, позволяют рассчитывать на их широ-кое практическое применение уже в ближайшем будущем: вели-чина критического тока таких кабелей достигает 6 кА (при Т  77 К, диаметр кабеля около 130 мм), получены и успешно испытаны образцы таких кабелей длиной 30-50 м, и в ближай-шие годы их длина достигнет 700-1000 м [13][14][15].…”

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High-Temperature Superconducting Materials with High Current-Carrying Characteristics and Methods of Their Fabrication

et al. 2004

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Развитие технологии получения ВТСП-материалов, которые могут не-сти бездиссипативные токи высокой плотности, привело к настоящему времени к появлению коммерческих сверхпроводящих кабелей, рабо-тающих при температуре жидкого азота, а также длинномерных пле-ночных ВТСП-материалов. При решении задачи повышения токонесу-щей способности металлооксидных купратов приходится решать две разнородные задачи: с одной стороны, необходимо получить материал с высоким совершенством кристаллической структуры, близким к моно-кристаллу, и с другой -для обеспечения высоких значений плотности критического тока образец должен содержать кристаллические дефек-ты, эффективно способствующие пиннингу вихрей Абрикосова. В рабо-те проводится анализ технологии обработки поликристаллических ВТСП-материалов, полученных традиционными методами механо-термической обработки с помощью мощной импульсной плазмы. Полу-ченные результаты сравниваются с нетрадиционными методами полу-чения ВТСП-материалов на примере тонкопленочной технологии хими-ческого осаждения из паровой фазы с применением металлоорганиче-ских соединений. Делается вывод о высокой перспективности именно нетрадиционных методов получения ВТСП-материалов с высокими то-конесущими характеристиками на основе металлооксидных сверхпро-водящих пленок. The development of technology of HTSC-materials with their outstandingУспехи физ. мет. / Usp. Fiz. Met. 2004, т. 5, сс. 167-218 Îòòèñêè äîñòóïíû íåïîñðåäñòâåííî îò èçäàòåëÿ Ôîòîêîïèðîâàíèå ðàçðåøåíî òîëüêî â ñîîòâåòñòâèè ñ ëèöåíçèåé 2004 ÈÌÔ (Èíñòèòóò ìåòàëëîôèçèêè èì. Ã. Â. Êóðäþìîâà ÍÀÍ Óêðàèíû) Íàïå÷àòàíî â Óêðàèíå.

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Numerical modeling of a HTS cable

Cited by 11 publications

References 8 publications

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Prediction of resistive and hysteretic losses in a multi-layer high-T_csuperconducting cable

High-Temperature Superconducting Materials with High Current-Carrying Characteristics and Methods of Their Fabrication

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Numerical modeling of a HTS cable

Cited by 11 publications

References 8 publications

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Computation of Losses in HTS Under the Action of Varying Magnetic Fields and Currents

Prediction of resistive and hysteretic losses in a multi-layer high-Tcsuperconducting cable

High-Temperature Superconducting Materials with High Current-Carrying Characteristics and Methods of Their Fabrication

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Prediction of resistive and hysteretic losses in a multi-layer high-T_csuperconducting cable