PhD subjects

1 sujet IRFU/DACM

Dernière mise à jour : 20-07-2019


««

• Mechanics, energetics, process engineering

 

Study of the Thermomechanical Behavior of the Superconductor Nb3Sn in Coils for Future Accelerator Magnets

SL-DRF-19-0486

Research field : Mechanics, energetics, process engineering
Location :

Département des Accélérateurs, de Cryogénie et de Magnétisme (DACM)

Laboratoire d'Etudes des Aimants Supraconducteurs (LEAS)

Saclay

Contact :

Etienne Rochepault

Olivier Hubert

Starting date : 01-10-2019

Contact :

Etienne Rochepault

CEA - DRF/IRFU/DACM

01 69 08 37 75

Thesis supervisor :

Olivier Hubert

ENS Pari-Saclay - LMT

01 47 40 22 24

Personal web page : https://www.researchgate.net/profile/Etienne_Rochepault

Laboratory link : http://irfu-i.cea.fr/dacm/index.php

In order to develop future particle accelerators such as the Future Circular Collider (FCC), high field superconducting electromagnets (higher than 15 T) are necessary. The superconductor Nb3Sn is aimed, however it causes some technical issues yet not solved during its production. The Nb3Sn is produced in the form of cables of the Rutherford type. These cables are then wound to form the coils of the electromagnet. Following winding, the conductor requires a heat treatment at 650°C in order to form the Nb3Sn superconducting phase. It is now established that significant dimensional changes of the strands occur during this phase change, translating in dimensional changes of the cables. If these changes in dimensions are not permitted by the tooling, mechanical stress add up in the coil and the superconducting performances degrade. Currently this issue is dealt with empirically by allowing clearances in central posts, around which are wound the superconducting cables, and by varying iteratively the clearances. However, the thermomechanical behavior of the Nb3Sn cables in a coil during the heat treatment needs to be quantified. The goal of this thesis is to observe and understand the changes of dimensions of this type of Nb3Sn conductors in order to help dimensioning the coil fabrication tooling for future accelerator magnets, and potentially improve their performances.

 

Retour en haut