Your search keyword '"M. Bajko"' showing total 11 results

1. Fiber Bragg Grating Cryosensors for Superconducting Accelerator Magnets

Author

A. Chiuchiolo, M. Bajko, J. C. Perez, H. Bajas, M. Consales, M. Giordano, G. Breglio, and A. Cusano

Subjects

Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

The design, fabrication, and tests of the new generation of superconducting magnets for the High Luminosity upgrade of the Large Hadron Collider (HL-LHC) require the support of an adequate sensing technology able to assure the integrity of the strain-sensitive and brittle superconducting cables through the whole service life of the magnet: assembly up to 150 MPa, cool down to 1.9 K, and powering up to about 16 kA. A precise temperature monitoring is also needed, in order to guarantee the safe working condition of the superconducting cables in the power transmission lines (SC-Link) designed to feed the magnet over long distance. Fiber Bragg Grating-based temperature and strain monitoring systems have been implemented in the first SC-Link prototype and in two subscale dipole magnets and tested in the cryogenic test facility at CERN, at 30 K, 77 K, and 1.9 K.

Published

2014

2. Construction and Test of the Enhanced Racetrack Model Coil, First CERN R&D Magnet for the FCC

Author

J. C. Perez, M. Bajko, N. Bourcey, B. Bordini, L. Bottura, Salvador Ferradas Troitino, E. Gautheron, M. Guinchard, S. Izquierdo Bermudez, F. Mangearotti, C. Petrone, D. Tommasini, and G. Willering

Subjects

Electrical and Electronic Engineering, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Published

2022

3. Power Test of the First Two HL-LHC Insertion Quadrupole Magnets Built at CERN

Author

F. J. Mangiarotti, G. Willering, L. Fiscarelli, M. Bajko, L. Bottura, V. Desbiolles, A. Devred, J. Ferradas Troitino, S. Izquierdo Bermudez, R. Keijzer, F. Lackner, A. Milanese, G. Ninet, H. Prin, E. Ravaioli, S. Russenschuck, E. Takala, and E. Todesco

Subjects

Physics::Instrumentation and Detectors, Physics::Accelerator Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Accelerators and Storage Rings, Electronic, Optical and Magnetic Materials

Abstract

The High-Luminosity project (HL-LHC) of the CERN Large Hadron Collider (LHC), requires low β* quadrupole magnets in Nb$_3$Sn technology that will be installed on each side of the ATLAS and CMS experiments. After a successful shortmodel magnet manufacture and test campaign, the project has advanced with the production, assembly, and test of full-size 7.15- m-long magnets. In the last two years, two CERN-built prototypes (MQXFBP1 and MQXFBP2) have been tested and magnetically measured at the CERN SM18 test facility. These are the longest accelerator magnets based on Nb$_3$Sn technology built and tested to date. In this paper, we present the test and analysis results of these two magnets, with emphasis on quenches and training, voltage-current measurements and the quench localization with voltage taps and a new quench antenna.

Published

2022

4. Final Prototypes, First Pre-series Units and Steps Towards Series Production of the LHC Main Dipoles

Author

F. Savary, M. Bajko, Marco Buzio, P. Fessia, L. Vanenkov, E. Todesco, G. Spigo, L. Bottura, P. Pugnat, Michele Modena, D. Perini, J. Vlogaert, W. Scandale, O. Pagano, S. Sanfilippo, C. Wyss, and A. Siemko

Subjects

Superconductivity, Physics, Large Hadron Collider, Field (physics), Physics::Instrumentation and Detectors, Superconducting magnet, Accelerators and Storage Rings, Synchrotron, law.invention, Nuclear physics, Dipole, law, Magnet, Collider

Abstract

The LHC, a 7 TeV proton collider presently under construction at CERN, requires 1232, superconducting dipole magnets, featuring a nominal field of 8.33 T inside a cold bore tube of 50 mm inner diameter and a magnetic length of 14.3 in. This paper summarises the results of the program of the six LHC main dipole final prototypes and presents the performance measurements of the first magnets of the 90 pre-series units currently under manufacture by industry. Results of geometric and magnetic measurements are given and discussed. Finally, the major milestones towards the dipole magnets series manufacture are given and commented.

Published

2001

5. First operational experience of the upgraded cryogenic infrastructure of the vertical magnet test facility in the SM18 hall, including HFM and cluster D test stations.

Author

V Benda, A Lees, O Pirotte, A Vande Craen, M Pezzetti, J P Lamboy, V Lefebvre, M Bajko, and C Giloux

Published

2019

6. Thermal performance of the new superfluid helium vertical test cryostats for magnet tests at CERN.

Author

A Vande Craen, M Bajko, V Benda, J-B Deschamps, C Giloux, A Lees, V Parma, F Pasdeloup, and O Pirotte

Published

2019

7. Powering of an HTS dipole insert-magnet operated standalone in helium gas between 5 and 85 K.

Author

J van Nugteren, G Kirby, H Bajas, M Bajko, A Ballarino, L Bottura, A Chiuchiolo, P-A Contat, M Dhallé, M Durante, P Fazilleau, A Fontalva, P Gao, W Goldacker, H ten Kate, A Kario, V Lahtinen, C Lorin, A Markelov, and J Mazet

Subjects

MAGNETIC dipoles, SUPERCONDUCTIVITY, ELECTRIC potential

Abstract

This paper describes the standalone magnet cold testing of the high temperature superconducting (HTS) magnet Feather-M2.1-2. This magnet was constructed within the European funded FP7-EUCARD2 collaboration to test a Roebel type HTS cable, and is one of the first high temperature superconducting dipole magnets in the world. The magnet was operated in forced flow helium gas with temperatures ranging between 5 and 85 K. During the tests a magnetic dipole field of 3.1 T was reached inside the aperture at a current of 6.5 kA and a temperature of 5.7 K. These values are in agreement with the self-field critical current of the used SuperOx cable assembled with Sunam tapes (low-performance batch), thereby confirming that no degradation occurred during winding, impregnation, assembly and cool-down of the magnet. The magnet was quenched many tens of times by ramping over the critical current and no degradation nor training was evident. During the tests the voltage over the coil was monitored in the microvolt range. An inductive cancellation wire was used to remove the inductive component, thereby significantly reducing noise levels. Close to the quench current, drift was detected both in temperature and voltage over the coil. This drifting happens in a time scale of minutes and is a clear indication that the magnet has reached its limit. All quenches happened approximately at the same average electric field and thus none of the quenches occurred unexpectedly. [ABSTRACT FROM AUTHOR]

Published

2018

8. Cryogenic test facility instrumentation with fiber optic and fiber optic sensors for testing superconducting accelerator magnets.

Author

A Chiuchiolo, H Bajas, M Bajko, B Castaldo, M Consales, A Cusano, M Giordano, C Giloux, J C Perez, L Sansone, and P Viret

Published

2017

9. Performance of the cold powered diodes and diode leads in the main magnets of the LHC.

Author

G P Willering, C Giloux, M Bajko, M Bednarek, L Bottura, Z Charifoulline, K Dahlerup-Petersen, G Dib, G D'Angelo, A Gharib, L Grand-Clement, S Izquierdo Bermudez, H Prin, V Roger, S Rowan, F Savary, J-Ph Tock, and A Verweij

Published

2015

10. The Characterization of Optical Fibers for Distributed Cryogenic Temperature Monitoring.

Author

Marcon L, Chiuchiolo A, Castaldo B, Bajas H, Galtarossa A, Bajko M, and Palmieri L

Abstract

Thanks to their characteristics, optical fiber sensors are an ideal solution for sensing applications at cryogenic temperatures, such as the monitoring of superconducting devices. Their applicability at such temperatures, however, is not immediate as optical fibers exhibit a non-linear thermal response which becomes rapidly negligible below 50 K. A thorough analysis of such a response down to cryogenic temperatures then becomes necessary to correctly translate the optical interrogation readings into the actual fiber temperature. Moreover, to increase the fiber sensitivity down to a few kelvin, special coatings can be used. In this manuscript we described the thermal responses experimental characterization of four commercially available optical fiber samples with different polymeric coatings in the temperature range from 5 K to 300 K: two with acrylate coatings of different thickness, one with a polyimide coating and one with a polyether-ether-ketone (PEEK) coating. Multiple thermal cycles were performed consecutively to guarantee the quality of the results and a proper estimate of the sensitivity of the various samples. Finally, we experimentally validated the quality of the measured thermal responses by monitoring the cool down of a dummy superconducting link from room temperature to approximately 50 K using two fibers coated, respectively, in acrylate and PEEK. The temperatures measured with the fibers agreed and matched those obtained by standard electronic sensors, providing, at the same time, further insight in to the cool-down evolution along the cryostat.

Published

2022

11. Cryogenic-temperature profiling of high-power superconducting lines using local and distributed optical-fiber sensors.

Author

Chiuchiolo A, Palmieri L, Consales M, Giordano M, Borriello A, Bajas H, Galtarossa A, Bajko M, and Cusano A

Abstract

This contribution presents distributed and multipoint fiber-optic monitoring of cryogenic temperatures along a superconducting power transmission line down to 30 K and over 20 m distance. Multipoint measurements were conducted using fiber Bragg gratings sensors coated with two different functional overlays (epoxy and poly methyl methacrylate (PMMA)) demonstrating cryogenic operation in the range 300-4.2 K. Distributed measurements exploited optical frequency-domain reflectometry to analyze the Rayleigh scattering along two concatenated fibers with different coatings (acrylate and polyimide). The integrated system has been placed along the 20 m long cryostat of a superconducting power transmission line, which is currently being tested at the European Organization for Nuclear Research (CERN). Cool-down events from 300-30 K have been successfully measured in space and time, confirming the viability of these approaches to the monitoring of cryogenic temperatures along a superconducting transmission line.

Published

2015