The FalconD project (Future Accelerator post-LHC Optimized Nb_{3}Sn Dipole), conducted by INFN Genoa and Milan in collaboration with CERN, is dedicated to the development of a 1.5 m long, 12 T Nb3Sn dipole. Nb3Sn has already proven its effectiveness in accelerator magnets, and its application to bending dipoles is a key step toward future high-field accelerator technologies. A major challenge of the design is the mechanical structure, which must withstand the substantial Lorentz forces generated by the high magnetic field. To address this, the innovative bladder and key (B {\&} K) concept is adopted, applied here for the first time to a cos-theta dipole. This contribution presents a 2D finite element mechanical analysis of the FalconD, focusing on stress distribution and gap evolution during the main assembly and operational stages, with the aim of validating the design approach.
Advancements in the Mechanical Structure Design of FalconD: The INFN-CERN Collaboration for the Nb$_{3}$Sn 12 T Cos-Theta Dipole Within the High-Field Magnets R&D Program / T. Maiello, A. Bersani, E. Bianchi, B. Caiffi, A. Dellacasagrande, S. Farinon, A. Foussat, A. Gagno, L. Musenich, A. Pampaloni, N. Sala, M. Sorbi, E. Todesco, R.U. Valente. - In: IEEE TRANSACTIONS ON APPLIED SUPERCONDUCTIVITY. - ISSN 1051-8223. - 36:5(2026 Aug), pp. 4901205.1-4901205.5. [10.1109/tasc.2026.3652970]
Advancements in the Mechanical Structure Design of FalconD: The INFN-CERN Collaboration for the Nb$_{3}$Sn 12 T Cos-Theta Dipole Within the High-Field Magnets R&D Program
M. Sorbi;
2026
Abstract
The FalconD project (Future Accelerator post-LHC Optimized Nb_{3}Sn Dipole), conducted by INFN Genoa and Milan in collaboration with CERN, is dedicated to the development of a 1.5 m long, 12 T Nb3Sn dipole. Nb3Sn has already proven its effectiveness in accelerator magnets, and its application to bending dipoles is a key step toward future high-field accelerator technologies. A major challenge of the design is the mechanical structure, which must withstand the substantial Lorentz forces generated by the high magnetic field. To address this, the innovative bladder and key (B {\&} K) concept is adopted, applied here for the first time to a cos-theta dipole. This contribution presents a 2D finite element mechanical analysis of the FalconD, focusing on stress distribution and gap evolution during the main assembly and operational stages, with the aim of validating the design approach.
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