Shielding efficiency and<i>E</i>(<i>J</i>) characteristics measured on large melt cast Bi-2212 hollow cylinders in axial magnetic fields

IEEE Trans. Appl. Supercond.

Kumar

et al. 2017

YBCO tubes of ~ 10 mm diameter closed at one extremity were engineered by a Buffer-Aided Top Seeded Melt Growth fabrication process (BA-TSMG). These tubes can act as efficient "dc" magnetic shields and are observed to reduce axial flux densities of 1.5 T by a factor of 100 at 20 K. Such performances are comparable in magnitude to the record threshold inductions reported for bulk MgB2 and Bi-2212 materials at lower temperatures. Magnetic shielding measurements for open and closed tubes at 77 K also show that the presence of the cap improves substantially the shielding performance at the closed extremity since it reduces the penetration through the open end. This fabrication technique is extremely promising for shielding "dc" stray fields generated by HTS magnets operated in a temperature range obtained by cryocoolers, liquid hydrogen (20 K) or liquid neon (27 K).

Section: Shielding Properties At 77 K In Liquid Nitrogencontrasting

confidence: 66%

Section: Introductionmentioning

confidence: 64%

Magnetic Shielding Above 1 T at 20 K With Bulk, Large Grain YBCO Tubes Made by Buffer-Aided Top Seeded Melt Growth

Wera

IEEE Trans. Appl. Supercond.

Kumar

et al. 2017

“…The equations have to be solved with the boundary (Dirichlet) conditions at infinity: 0, = A (9) and 0, = φ (10) that have been implemented by using a Jacobian transformation for sending the outer surface of a spherical shell to infinity [38]. The geometry studied in the present work is a hollow cylinder of finite height with two slits made in a vertical plane along a diameter.…”

Section: Modelmentioning

confidence: 99%

“…The present work deals with enclosures made of bulk high temperature superconductors (HTS). They can be used either at liquid nitrogen temperature (77 K) -at which magnetic shielding occurs up to a few tens of mT -or at low temperature (10 K and below) where shielding of magnetic fields in excess of 1 tesla was demonstrated recently [8,9]. Several materials are candidates for efficient magnetic screens, including MgB 2 [8,10], YBa 2 Cu 3 O 7 [3,11] or Bi-based compounds [12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Magnetic shielding properties of a superconducting hollow cylinder containing slits: modelling and experiment

Supercond. Sci. Technol.

Elschner

Hobl

et al. 2012

Self Cite

This paper deals with the magnetic properties of bulk high temperature superconducting cylinders used as magnetic shields. We investigate, both numerically and experimentally, the magnetic properties of a hollow cylinder with two axial slits which cut the cylinder in equal halves. Finite Element Method (FEM) modelling has been used with a threedimensional geometry to help us in understanding how the superconducting currents flow in such a cut cylinder and therefore how the magnetic shielding properties are affected, depending on the magnetic field orientation. Modelling results show that the slits block the shielding currents flow and act as an "entrance channel" for the magnetic flux lines. The contribution of the slits to the total flux density that enters the cylinder is studied through the angle formed between the applied field and the internal field. The modelled data agree nicely with magnetic shielding properties measured on a bulk Bi-2212 hollow cylinder at 77 K. The results demonstrate that the magnetic flux penetration in such a geometry can be modelled successfully using only two parameters of the superconductor (constant J c and n value), which were determined from magnetic measurements on the plain cylinder.

“…HTS materials can be used either at liquid nitrogen temperature, where shielding remains effective up to a few mT, or at lower temperatures (e.g. typically 10 K or lower), where shielding of magnetic inductions in excess of 1 tesla has been successfully demonstrated using hollow cylinders made of Bi-2212 [12] or MgB2 [13].…”

Section: Introductionmentioning

confidence: 99%

Magnetic shielding of an inhomogeneous magnetic field source by a bulk superconducting tube

Hogan

Supercond. Sci. Technol.

Wera

et al. 2015

Self Cite

Bulk type-II irreversible superconductors can act as excellent passive magnetic shields, with a strong attenuation of low frequency magnetic fields. Up to now, the performances of superconducting magnetic shields have mainly been studied in a homogenous magnetic field, considering only immunity problems , i.e. when the field is applied outside the tube and the inner field should ideally be zero. In this paper, we aim to investigate experimentally and numerically the magnetic response of a high-Tc bulk superconducting hollow cylinder at 77 K in an emission problem, i.e. when subjected to the non-uniform magnetic field generated by a source coil placed inside the tube. A bespoke 3-D mapping system coupled with a 3-axis Hall probe is used to measure the magnetic flux density distribution outside the superconducting magnetic shield. A finite element model is developed to understand how the magnetic field penetrate s into the superconductor and how the induced superconducting shielding currents flow inside the shield in the case where the emitting coil is placed coaxially inside the tube. The finite element modelling is found to be in excellent agreement with the experimental data. Results show that a concentration of the magnetic flux lines occurs between the emitting coil and the superconducting screen. This effect is observed both with the modelling and the experiment. In the case of a long tube, we show that the main features of the field penetration in the superconducting walls can be reproduced with a simple analytical 1D model. This model is used to estimate the maximum flux density of the emitting coil that can be shielded by the superconductor .