Design, fabrication and performance of a 1.29 T Bi-2223 magnet

The dynamic property of a high temperature superconductor (HTS) coil which possesses short circuits between windings was investigated by magnetic measurement. Based on a general lock-in technique, the net magnetomotive force (mmf) provided by a short circuit coil carrying ac current is given in two parameters: the imaginary part of the mmf accounting for the power dissipation in the coil, and the real part of the mmf relating to the flux and attractive force in the magnetic circuit. These two terms are given in a broad range of current amplitude A and frequency f , which cover the main operational region for typical controllability requirements and other dynamic applications. An equivalent circuit model based on the assumption that the short circuits are formed by a group of closed circuits located coaxially with the coil was proposed. The parameters of the circuit are determined by fitting the experimental results in some specific cases. The feasibility and efficiency of the equivalent circuit concerning its applications at low and high frequency are discussed respectively.

Section: Hts Coil Design and Fabricationmentioning

confidence: 99%

AC analysis of a high temperature superconductor coil with short circuits

Gu¹,

Zhuang²,

Han³

2005

“…Following the development of the over pressure processing technique, the critical current I c (self-field) of the tape has been significantly improved by a factor of 30-40% [1,2], reaching a value of 200 A in 77 K. When the tape is used in applications, an auxiliary way is often used to increase the I c further by introducing ferromagnetic shielding (FS), which can guide the flux away from the superconductor region. In [3][4][5][6], iron yokes installed at the end of the coil were used to reduce the field at the outmost pancake, a place exposed to the strongest perpendicular field. This technique was also widely adopted in tape applications.…”

Section: Introductionmentioning

confidence: 99%

Simulation of ferromagnetic shielding to the critical current of Bi2223/Ag tape under external fields

Gu¹,

Alamgir²,

Qu³

et al. 2007

Ferromagnetic material was electroplated onto the surface of the Bi2223/Ag multi-filamentary tape and as a result changed the Ic(B) characteristic of the tape correspondingly. A numerical simulation was used to investigate the influence of ferromagnetic shielding (FS) on the performance of the tape, in particular the Ic behaviour under perpendicular external fields. Using finite element analysis, we are able to understand how FS alters the flux distribution within the superconductor region under any arbitrary shielding structure. The shielding width, thickness and nonlinear property of the ferromagnetic material were taken into account for the simulation. Finally, optimized shielding parameters in association with different operating fields were suggested and these values could be considered for the next run of experimental work.

“…The substantially increased current-carrying capacity and reduced I c anisotropy of Bi-2223 at decreased temperatures (20-30 K) enable the production of cryogenfree magnet systems [8,9]. Cryogen-free systems with a temperature window 20-30 K allow generating much higher magnetic fields than using liquid nitrogen; no cryogen is required, the cooling efficiency is high, and the system is much more economical than that for 4.2 K. A 1.29 T laboratory sized Bi-2223 magnet operating at 4.2 K has been fabricated from six epoxy resin impregnated double-wound pancakes of inner diameter 40 mm made by the R&W technique [10]. Cryogenfree Bi-2223 systems have been made using stacked pancake coils producing fields of 7 T [11] at around 20 K. Recently, Richens et al [12] have presented Bi-2223 coil successfully operated by conduction cooling by a two-stage cryocooler in the temperature range 12-50 K. Their thermal stability studies have shown that thermal run-away is sufficiently controlled and damage can be readily prevented.…”

Section: Introductionmentioning

confidence: 99%

The design and performance of a Bi-2223/Ag magnet cooled by a single-stage cryocooler

Kopera¹,

Melíšek²,

Kòváč³

et al. 2005

The design and fabrication of a split coil Bi-2223/Ag tape superconducting magnet cooled by a single-stage cryocooler is presented. The magnet consists of six double-wound pancakes impregnated by epoxy resin with inner diameter 50 mm and outer diameter 98 mm. Critical currents of individual pancakes, double pancakes and the whole magnet are measured, calculated and discussed. The magnet's performance was tested at liquid helium and nitrogen temperatures as well as at solid nitrogen temperatures and cooled by an AL230 single-stage Gifford-McMahon cycle cryorefrigerator. The measured magnet currents are compared with those estimated by calculations using short sample data.