CERN Accelerating science

Published Articles
Report number FERMILAB-PUB-19-055-TD
Title Test Results of the CERN HL-LHC low-$\beta$ Quadrupole Short Models MQXFS3c and MQXFS4
Author(s) Mangiarotti, Franco J (CERN) ; Bajas, Hugues (CERN) ; Ambrosio, Giorgio (Fermilab) ; Bajko, Marta (CERN) ; Bordini, Bernardo (CERN) ; Bourcey, Nicolas (CERN) ; Duda, Michal (Cracow, INP ; CERN) ; Desbiolles, Vincent (CERN) ; Feuvrier, Jerome (CERN) ; Fleiter, Jerome (CERN) ; Izquierdo Bermudez, Susana (CERN) ; Chiuchiolo, Antonella (CERN) ; Devred, Arnaud (CERN) ; Ferracin, Paolo (CERN) ; Fiscarelli, Lucio (CERN) ; Mentink, Matthias (CERN) ; Nobrega, Alfred (Fermilab) ; Pepitone, Kevin (Uppsala U. (main)) ; Ravaioli, Emmanuele (CERN) ; Schmalzle, Jesse (Brookhaven Natl. Lab.) ; Todesco, Ezio (CERN) ; Perez, Juan Carlos (CERN) ; Vallone, Giorgio (LBL, Berkeley) ; Willering, Gerard (CERN) ; Yu, Miao (Fermilab)
Collaboration LARP
Publication 2019
Imprint 2019-02-04
Number of pages 5
In: IEEE Trans. Appl. Supercond. 29, 5 (2019) pp.4001705
In: Applied Superconductivity Conference 2018, Seattle, United States Of America, 28 Oct - 2 Nov 2018, pp.4001705
DOI 10.1109/TASC.2019.2897229
Subject category Accelerators and Storage Rings
Accelerator/Facility, Experiment LARP
Abstract For the High Luminosity Upgrade of the CERN Large Hadron Collider, lower $\beta$* quadrupole magnets based on advanced Nb3Sn conductors will be installed on each side of the ATLAS and CMS experiment insertion zones. As part of the technological developments needed to achieve the required field gradient of 132.6 T/m within a 150-mm aperture, short length model magnets, named MQXFS, are tested both at the CERN SM18 and FERMI Lab test facilities. The model magnets rely on two types of Nb3Sn conductors (RRP and PIT) and on an innovative bladders and keys design to provide mechanical support against the Lorentz forces. In 2016 and 2017, the powering tests of the first two models MQXFS3 (RRP) and MQXFS5 (PIT) proved that nominal performance (16.5 kA) could be reached with excellent memory of the quench current after thermal cycle. However both magnets showed a slow training behavior with clear observations of voltage disturbances before the quench. Besides MQXFS5 only could reach ultimate current (17.9 kA) whereas erratic behavior was observed on MQXFS3 due to conductor local degradation at the head of one of the coil. In 2018, this limiting coil was changed and the applied azimuthal pre-stress increased. If ultimate current could then be reached, no stable current could be maintained due to identified defect on the outer layer of the new coil. Finally the outcome of the test of the new model MQXFS4, featuring the final RRP conductors that will be used for the series production and variation on the inner layer quench heater designs are here reported in details.

Corresponding record in: Inspire


 Δημιουργία εγγραφής 2019-06-04, τελευταία τροποποίηση 2020-08-28


Πλήρες κείμενο:
Κατέβασμα πλήρες κειμένου
PDF