Your search keyword '"Laan, D."' showing total 41 results

1. Development and performance of a 2.9 Tesla dipole magnet using high-temperature superconducting CORC®wires

Author

Wang, X, Abraimov, D, Arbelaez, D, Bogdanof, TJ, Brouwer, L, Caspi, S, DIetderich, DR, DImarco, J, Francis, A, Garcia Fajardo, L, Ghiorso, WB, Gourlay, SA, Higley, HC, Marchevsky, M, Maruszewski, MA, Myers, CS, Prestemon, SO, Shen, T, Taylor, J, Teyber, R, Turqueti, M, Van Der Laan, D, and Weiss, JD

Subjects

REBCO, dipole accelerator magnet, CORC&#174, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics

Abstract

Although the high-temperature superconducting (HTS) REBa2Cu3O x (REBCO, RE-rare earth elements) material has a strong potential to enable dipole magnetic fields above 20 T in future circular particle colliders, the magnet and conductor technology needs to be developed. As part of an ongoing development to address this need, here we report on our CORC® canted cosθ magnet called C2 with a target dipole field of 3 T in a 65 mm aperture. The magnet was wound with 70 m of 3.8 mm diameter CORC® wire on machined metal mandrels. The wire had 30 commercial REBCO tapes from SuperPower Inc. each 2 mm wide with a 30 µm thick substrate. The magnet generated a peak dipole field of 2.91 T at 6.290 kA, 4.2 K. The magnet could be consistently driven into the flux-flow regime with reproducible voltage rise at an engineering current density between 400-550 A mm-2, allowing reliable quench detection and magnet protection. The C2 magnet represents another successful step towards the development of high-field accelerator magnet and CORC® conductor technologies. The test results highlighted two development needs: continue improving the performance and flexibility of CORC® wires and develop the capability to identify locations of first onset of flux-flow voltage.

Published

2021

2. A viable dipole magnet concept with REBCO CORC® wires and further development needs for high-field magnet applications

Author

Wang, X, Caspi, S, Dietderich, DR, Ghiorso, WB, Gourlay, SA, Higley, HC, Lin, A, Prestemon, SO, Van Der Laan, D, and Weiss, JD

Subjects

REBCO, dipole magnet, CORC, General Physics, Condensed Matter Physics, Materials Engineering, Electrical and Electronic Engineering

Abstract

REBCO coated conductors maintain a high engineering current density above 16 T at 4.2 K. That fact will significantly impact markets of various magnet applications including high-field magnets for high-energy physics and fusion reactors. One of the main challenges for the high-field accelerator magnet is the use of multi-tape REBCO cables with high engineering current density in magnet development. Several approaches developing high-field accelerator magnets using REBCO cables are demonstrated. In this paper, we introduce an alternative concept based on the canted cos θ (CCT) magnet design using conductor on round core (CORC®) wires that are wound from multiple REBCO tapes with a Cu core. We report the development and test of double-layer three-turn CCT dipole magnets using CORC® wires at 77 and 4.2 K. The scalability of the CCT design allowed us to effectively develop and demonstrate important magnet technology features such as coil design, winding, joints and testing with minimum conductor lengths. The test results showed that the CCT dipole magnet using CORC® wires was a viable option in developing a REBCO accelerator magnet. One of the critical development needs is to increase the engineering current density of the 3.7 mm diameter CORC® wire to 540 A mm-2 at 21 T, 4.2 K and to reduce the bending radius to 15 mm. This would enable a compact REBCO dipole insert magnet to generate a 5 T field in a background field of 16 T at 4.2 K.

Published

2018

3. Prediction of strain, inter-layer interaction and critical current in CORC® wires under axial strain by T-A modeling

Author

Wang, K, primary, Gao, Y W, additional, Anvar, V A, additional, Radcliff, K, additional, Weiss, J D, additional, van der Laan, D C, additional, Zhou, Y H, additional, and Nijhuis, A, additional

Published

2022

4. Enhanced critical axial tensile strain limit of CORC® wires: FEM and analytical modeling

Author

Anvar, V A, primary, Wang, K, additional, Weiss, J D, additional, Radcliff, K, additional, van der Laan, D C, additional, Hossain, M S A, additional, and Nijhuis, A, additional

Published

2022

5. AC losses of Roebel and CORC® cables at higher AC magnetic fields and ramp rates

Author

Sumption, M D, primary, Murphy, J P, additional, Haugan, T, additional, Majoros, M, additional, van der Laan, D C, additional, Long, N, additional, and Collings, E W, additional

Published

2021

6. High-temperature superconducting CORC® wires with record-breaking axial tensile strain tolerance present a breakthrough for high-field magnets

Author

van der Laan, D C, primary, Radcliff, K, additional, Anvar, V A, additional, Wang, K, additional, Nijhuis, A, additional, and Weiss, J D, additional

Published

2021

7. SMART conductor on round core (CORC®) wire via integrated optical fibers

Author

Scurti, F, primary, Weiss, J D, additional, van der Laan, D C, additional, and Schwartz, J, additional

Published

2021

8. Quench detection using Hall sensors in high-temperature superconducting CORC®-based cable-in-conduit-conductors for fusion applications

Author

Weiss, J D, primary, Teyber, R, additional, Marchevsky, M, additional, and van der Laan, D C, additional

Published

2020

9. CORC® wires containing integrated optical fibers for temperature and strain monitoring and voltage wires for reliable quench detection

Author

van der Laan, D C, primary, Weiss, J D, additional, Scurti, F, additional, and Schwartz, J, additional

Published

2020

10. AC loss and contact resistance in REBCO CORC®, Roebel, and stacked tape cables

Author

Yagotintsev, K, primary, Anvar, V A, additional, Gao, P, additional, Dhalle, M J, additional, Haugan, T J, additional, Van Der Laan, D C, additional, Weiss, J D, additional, Hossain, M S A, additional, and Nijhuis, A, additional

Published

2020

11. A CORC® cable insert solenoid: the first high-temperature superconducting insert magnet tested at currents exceeding 4 kA in 14 T background magnetic field

Author

Van Der Laan, D C, primary, Weiss, J D, additional, Trociewitz, U P, additional, Abraimov, D, additional, Francis, A, additional, Gillman, J, additional, Davis, D S, additional, Kim, Y, additional, Griffin, V., additional, Miller, G, additional, Weijers, H W, additional, Cooley, L D, additional, Larbalestier, D C, additional, and Wang, X R, additional

Published

2020

12. Introduction of the next generation of CORC® wires with engineering current density exceeding 650 A mm−2 at 12 T based on SuperPower’s ReBCO tapes containing substrates of 25 μm thickness

Author

Weiss, J D, primary, van der Laan, D C, additional, Hazelton, D, additional, Knoll, A, additional, Carota, G, additional, Abraimov, D, additional, Francis, A, additional, Small, M A, additional, Bradford, G, additional, and Jaroszynski, J, additional

Published

2020

13. Effect of monotonic and cyclic axial tensile stress on the performance of superconducting CORC® wires

Author

van der Laan, D C, primary, McRae, D M, additional, and Weiss, J D, additional

Published

2019

14. Status of CORC® cables and wires for use in high-field magnets and power systems a decade after their introduction

Author

van der Laan, D C, primary, Weiss, J D, additional, and McRae, D M, additional

Published

2019

15. Effect of transverse compressive monotonic and cyclic loading on the performance of superconducting CORC® cables and wires

Author

van der Laan, D C, primary, McRae, D M, additional, and Weiss, J D, additional

Published

2018

16. Erratum: Bending of CORC® cables and wires: finite element parametric study and experimental validation (2018 Supercond. Sci. Technol. 31 115006)

Author

Anvar, V A, primary, Ilin, K, additional, Yagotintsev, K A, additional, Monachan, B, additional, Ashok, K B, additional, Kortman, B A, additional, Pellen, B, additional, Haugan, T J, additional, Weiss, J D, additional, van der Laan, D C, additional, Thomas, R J, additional, Prakash, M Jose, additional, Hossain, M S A, additional, and Nijhuis, A, additional

Published

2018

17. Bending of CORC® cables and wires: finite element parametric study and experimental validation

Author

Anvar, V A, primary, Ilin, K, additional, Yagotintsev, K A, additional, Monachan, B, additional, Ashok, K B, additional, Kortman, B A, additional, Pellen, B, additional, Haugan, T J, additional, Weiss, J D, additional, van der Laan, D C, additional, Thomas, R J, additional, Prakash, M Jose, additional, Hossain, M S A, additional, and Nijhuis, A, additional

Published

2018

18. Development of CORC® cables for helium gas cooled power transmission and fault current limiting applications

Author

van der Laan, D C, primary, Weiss, J D, additional, Kim, C H, additional, Graber, L, additional, and Pamidi, S, additional

Published

2018

19. Proceedings of the 8th Workshop on Mechanical and Electromagnetic Properties of Composite Superconductors (MEM 2016)

Author

van der Laan, D C, primary, Larbalestier, D C, additional, Godeke, A, additional, and Osamura, K, additional

Published

2017

20. Record current density of 344 A mm−2at 4.2 K and 17 T in CORC®accelerator magnet cables

Author

van der Laan, D C, primary, Weiss, J D, additional, Noyes, P, additional, Trociewitz, U P, additional, Godeke, A, additional, Abraimov, D, additional, and Larbalestier, D C, additional

Published

2016

21. Stability and normal zone propagation in YBCO CORC cables

Author

Majoros, M, primary, Sumption, M D, additional, Collings, E W, additional, and van der Laan, D, additional

Published

2016

22. Behavior of a high-temperature superconducting conductor on a round core cable at current ramp rates as high as 67.8 kA s−1in background fields of up to 19 T

Author

Michael, P C, primary, Bromberg, L, additional, van der Laan, D C, additional, Noyes, P, additional, and Weijers, H W, additional

Published

2016

23. Engineering current density in excess of 200 A mm−2at 20 T in CORC®magnet cables containing RE-Ba2Cu3O7−δtapes with 38μm thick substrates

Author

van der Laan, D C, primary, Goodrich, L F, additional, Noyes, P, additional, Trociewitz, U P, additional, Godeke, A, additional, Abraimov, D, additional, Francis, A, additional, and Larbalestier, D C, additional

Published

2015

24. Magnetization ac loss reduction in HTS CORC®cables made of striated coated conductors

Author

Vojenčiak, M, primary, Kario, A, additional, Ringsdorf, B, additional, Nast, R, additional, van der Laan, D C, additional, Scheiter, J, additional, Jung, A, additional, Runtsch, B, additional, Gömöry, F, additional, and Goldacker, W, additional

Published

2015

25. Temperature- and field-dependent characterization of a conductor on round core cable

Author

Barth, C, primary, Laan, D C van der, additional, Bagrets, N, additional, Bayer, C M, additional, Weiss, K-P, additional, and Lange, C, additional

Published

2015

26. Experiments and FE modeling of stress–strain state in ReBCO tape under tensile, torsional and transverse load

Author

Ilin, K, primary, Yagotintsev, K A, additional, Zhou, C, additional, Gao, P, additional, Kosse, J, additional, Otten, S J, additional, Wessel, W A J, additional, Haugan, T J, additional, van der Laan, D C, additional, and Nijhuis, A, additional

Published

2015

27. Effect of variations in terminal contact resistances on the current distribution in high-temperature superconducting cables

Author

Willering, G P, primary, van der Laan, D C, additional, Weijers, H W, additional, Noyes, P D, additional, Miller, G E, additional, and Viouchkov, Y, additional

Published

2015

28. Magnetization losses in superconducting YBCO conductor-on-round-core (CORC) cables

Author

Majoros, M, primary, Sumption, M D, additional, Collings, E W, additional, and van der Laan, D C, additional

Published

2014

29. Characterization of a high-temperature superconducting conductor on round core cables in magnetic fields up to 20 T

Author

van der Laan, D C, primary, Noyes, P D, additional, Miller, G E, additional, Weijers, H W, additional, and Willering, G P, additional

Published

2013

30. High-current dc power transmission in flexible RE–Ba2Cu3O7 − δcoated conductor cables

Author

van der Laan, D C, primary, Goodrich, L F, additional, and Haugan, T J, additional

Published

2011

31. Anisotropic in-plane reversible strain effect in Y0.5Gd0.5Ba2Cu3O7 − δcoated conductors

Author

van der Laan, D C, primary, Abraimov, D, additional, Polyanskii, A A, additional, Larbalestier, D C, additional, Douglas, J F, additional, Semerad, R, additional, and Bauer, M, additional

Published

2011

32. Compact GdBa2Cu3O7–δcoated conductor cables for electric power transmission and magnet applications

Author

van der Laan, D C, primary, Lu, X F, additional, and Goodrich, L F, additional

Published

2011

33. Evidence that the reversible strain effect on critical current density and flux pinning in Bi2Sr2Ca2Cu3Oxtapes is caused entirely by the pressure dependence of the critical temperature

Author

Laan, D C van der, primary, Douglas, J F, additional, Clickner, C C, additional, Stauffer, T C, additional, Goodrich, L F, additional, and Eck, H J N van, additional

Published

2010

34. Effect of strain, magnetic field and field angle on the critical current density of Y Ba2Cu3O7−δcoated conductors

Author

van der Laan, D C, primary, Ekin, J W, additional, Douglas, J F, additional, Clickner, C C, additional, Stauffer, T C, additional, and Goodrich, L F, additional

Published

2010

35. The effect of strain on grains and grain boundaries in YBa2Cu3O7−δcoated conductors

Author

van der Laan, D C, primary, Haugan, T J, additional, Barnes, P N, additional, Abraimov, D, additional, Kametani, F, additional, Larbalestier, D C, additional, and Rupich, M W, additional

Published

2009

36. YBa2Cu3O7−δcoated conductor cabling for low ac-loss and high-field magnet applications

Author

van der Laan, D C, primary

Published

2009

37. Dependence of the critical current of YBa2Cu3O7−δcoated conductors on in-plane bending

Author

van der Laan, D C, primary and Ekin, J W, additional

Published

2008

38. Delamination strength of YBCO coated conductors under transverse tensile stress

Author

Laan, D C van der, primary, Ekin, J W, additional, Clickner, C C, additional, and Stauffer, T C, additional

Published

2007

39. Direct experimental analysis of the relation between the grain structure and the distribution of critical current density in YBa2Cu3Oxcoated conductors

Author

Laan, D C van der, primary, Dhallé, M, additional, Naveira, L M, additional, Eck, H J N van, additional, Metz, A, additional, Schwartz, J, additional, Davidson, M W, additional, Haken, B ten, additional, and Kate, H H J ten, additional

Published

2005

40. Critical current versus strain research at the University of Twente

Author

Eck, H J N van, primary, Laan, D C van der, additional, Dhall, M, additional, Haken, B ten, additional, and Kate, H H J ten, additional

Published

2003

41. Direct experimental analysis of the relation between the grain structure and the distribution of critical current density in YBa2Cu3Oxcoated conductors

Author

van der Laan, D C, Dhallé, M, Naveira, L M, van Eck, H J N, Metz, A, Schwartz, J, Davidson, M W, ten Haken, B, and ten Kate, H H J

Abstract

We present a relatively simple experimental method to correlate the grain structure of YBa2Cu3Oxcoated conductors with spatial variations of the critical current density on a macroscopic scale. Variations of the current density on a micrometre scale are visualized with magneto-optical imaging, using the flux trapped by colonies of grains to quantify the degree of connectivity. Integrating these trapped flux profiles over larger distances yields direct information of the critical current distribution on a millimetre scale, provided that contributions from negative return flux in colony boundaries are properly eliminated. Flux polarity is determined using the wavelength dependence of the Verdet constant. The validity of this analysis is demonstrated by comparing the results with direct transport data on the lateral current distribution, measured with the magnetic knife technique. The combination of both experiments shows that the critical current density is suppressed over several millimetres of conductor length at areas where a large number of high-angle grain boundaries or defects are present.

Published

2005