Your search keyword '"M. Guinchard"' showing total 5 results

1. First Short Orbit Nested Corrector Magnet for HL-LHC Produced in the Industry

Author

C. Martins Jardim, C. Alcazar, M. A. Dominguez, O. Duran, A. Estevez, J. A. Garcia-Matos, L. Garcia-Tabares, L. Gonzalez, P. Gomez, J. Jimenez, L. M. Martinez, T. Martinez, J. A. Pardo, J. M. Perez, P. Sobrino, F. Toral, I. Basabe, G. Hernando, M. Lopez, J. Lucas, M. Onate, S. Ferradas, L. Fiscarelli, M. Guinchard, J. C. Perez, P. Rogacki, E. Todesco, and G. Willering

Subjects

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

Published

2023

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. Fabrication and Power Test of Last MCBXFB Magnets

Author

Carla Martins Jardim, C. Alcazar, M. A. Dominguez, O. Duran, A. Estevez, J. A. Garcia-Matos, L. Garcia-Tabares, L. Gonzalez, P. Gomez, J. Jimenez, L. M. Martinez, T. Martinez, J. A. Pardo, J. M. Perez, P. Sobrino, F. Toral, S. Ferradas, L. Fiscarelli, M. Guinchard, J. C. Perez, E. Todesco, and G. Willering

Subjects

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

Published

2022

4. Optimizing the use of pressurized bladders for the assembly of HL-LHC MQXFB magnets

Author

J Ferradas Troitino, G Ambrosio, N Bourcey, D Cheng, A Devred, H Felice, P Ferracin, M Guinchard, S Izquierdo Bermudez, K Kandemir, N Lusa, A Milanese, S Mugnier, J C Perez, E Todesco, S Triquet, and G Vallone

Subjects

Accelerator Physics (physics.acc-ph), Materials Chemistry, Metals and Alloys, Ceramics and Composites, FOS: Physical sciences, Physics - Accelerator Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Accelerators and Storage Rings, physics.acc-ph

Abstract

The use of pressurized bladders for stress control of superconducting magnets was firstly proposed at Lawrence Berkeley National Laboratory in the early 2000s. Since then, the so-called ‘bladders and keys’ procedure has become one of the reference techniques for the assembly of high-field accelerator magnets and demonstrators. Exploiting the advantages of this method is today of critical importance for Nb$_{3}$Sn-based accelerator magnets, whose production requires the preservation of tight stress targets in the superconducting coils to limit the effects of the strain sensitivity and brittleness of the conductor. The present manuscript reports on the results of an experimental campaign focused on the optimization of the ‘bladders and keys’ assembly process in the MQXFB quadrupoles. These 7.2 m long magnets shall be among the first Nb$_{3}$Sn cryomagnets to be installed in a particle accelerator as a part of the High Luminosity upgrade of the LHC. One of the main practical implications of the bladders technique, especially important when applied to long magnets like MQXFB, is that to insert the loading keys, the opening of a certain clearance in the support structure is required. The procedure used so far for MQXF magnets involved an overstress in the coils during bladder inflation. The work presented here shows that such an overshoot can be eliminated thanks to additional bladders properly positioned in the structure. This optimized method was validated in a short model magnet and in a full-length mechanical model, becoming the new baseline for the series production at CERN Furthermore, the results are supported by numerical predictions using finite element models. The use of pressurized bladders for stress control of superconducting magnets was firstly proposed at Lawrence Berkeley National Laboratory (LBNL) in the early 2000s. Since then, the so-called “bladders and keys” procedure has become one of the reference techniques for the assembly of high-feld accelerator magnets and demonstrators. Exploiting the advantages of this method is today of critical importance for Nb3Sn-based accelerator magnets, whose production requires the preservation of tight stress targets in the superconducting coils to limit the effects of the strain sensitivity and brittleness of the conductor. The present manuscript reports on the results of an experimental campaign focused on the optimization of the “bladders and keys” assembly process in the MQXFB quadrupoles. These 7.2 m long magnets shall be among the frst Nb3Sn cryomagnets to be installed in a particle accelerator as a part of the High Luminosity upgrade of the LHC. One of the main practical implications of the bladders technique, especially important when applied to long magnets like MQXFB, is that to insert the loading keys, the opening of a certain clearance in the support structure is required. The procedure used so far for MQXF magnets involved an overstress in the coils during bladder infation. The work presented here shows that such an overshoot can be eliminated thanks to additional bladders properly positioned in the structure. This optimized method was validated in a short model magnet and in a full-length mechanical model, becoming the new baseline for the series production at CERN. Furthermore, the results are supported by numerical predictions using Finite Element models. The use of pressurized bladders for stress control of superconducting magnets was firstly proposed at Lawrence Berkeley National Laboratory (LBNL) in the early 2000s. Since then, the so-called bladders and keys procedure has become one of the reference techniques for the assembly of high-field accelerator magnets and demonstrators. Exploiting the advantages of this method is today of critical importance for Nb3Sn-based accelerator magnets, whose production requires the preservation of tight stress targets in the superconducting coils to limit the effects of the strain sensitivity and brittleness of the conductor. The present manuscript reports on the results of an experimental campaign focused on the optimization of the bladders and keys assembly process in the MQXFB quadrupoles. These 7.2 m long magnets shall be among the first Nb3Sn cryomagnets to be installed in a particle accelerator as a part of the High Luminosity upgrade of the LHC. One of the main practical implications of the bladders technique, especially important when applied to long magnets like MQXFB, is that to insert the loading keys, the opening of a certain clearance in the support structure is required. The procedure used so far for MQXF magnets involved an overstress in the coils during bladder inflation. The work presented here shows that such an overshoot can be eliminated thanks to additional bladders properly positioned in the structure. This optimized method was validated in a short model magnet and in a full-length mechanical model, becoming the new baseline for the series production at CERN. Furthermore, the results are supported by numerical predictions using Finite Element models.

Published

2023

5. Distributed optical strain sensing measurements down to cryogenic temperatures

Author

K. Kandemir, M. Guinchard, M. Crouvizier, O. Sacristan, and S. Mugnier

Subjects

Electrical and Electronic Engineering, Engineering (miscellaneous), Atomic and Molecular Physics, and Optics

Abstract

Rayleigh backscattering (RBS)-based distributed fiber sensors technology is becoming more and more crucial in various fields such as aerospace and defense, automotive, civil, and geotechnical. This technology is measuring the naturally occurring Rayleigh backscatter level in the optical fiber core; thus, any standard single-mode telecom optical fiber can be used. The application of distributed optical fiber strain sensing in the harsh environments of the European Organization for Nuclear Research required several mechanical tests to study the accuracy of strain sensing in cryogenic conditions. This study compares the performance of a RBS-based distributed optical fiber strain sensing down to cryogenic temperatures (4.2 K) with previously validated instrumentations such as electrical strain gauges and fiber Bragg grating technologies.

Published

2023