Strategy for the Simulation of the ITER Toroidal Field Coil Case Welding Distortion With Finite-Element Method

The first European superconducting winding pack (WP) and the first set of coil cases [toroidal field coil cases (TFCC)] for ITER are going to be delivered in 2017. The TFCC are steel structures that provide structural integrity to the WP, contribute to neutron shielding capacity, provide support to...

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Veröffentlicht in:IEEE transactions on applied superconductivity 2018-04, Vol.28 (3), p.1-5
Hauptverfasser: Jimenez, Marc, Cornelis, M., Damone, M., Kostopoulos, C., Libens, K., Heikkinen, S., Harrison, R., Hernandez, A., LoBue, A., Pellicer, N., Poncet, L., Bellesia, B., Veredas, G., Viladiu, E., Malpica, O., Barbero, P., Bolla, M., Francone, R., Spagnolo, M., Falcitelli, G., Cornella, J., Aprili, P., Barbero, E., Batista, R., Oliva, A. Bonito, Boter, E., Casas, P.
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Sprache:eng
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Zusammenfassung:The first European superconducting winding pack (WP) and the first set of coil cases [toroidal field coil cases (TFCC)] for ITER are going to be delivered in 2017. The TFCC are steel structures that provide structural integrity to the WP, contribute to neutron shielding capacity, provide support to operating forces, and offer interface connections with the rest of the ITER machine. The TFCC assembly is formed by four main parts: two sectors with U-shaped section and two closure plates, which, after being welded together, enclose the WP. Each TFCC weights about 150 t and presents a wall thickness from 60 to 120 mm. The presence of distortions when welding such thick structures is particularly problematic in these components, which require tight tolerances and include several interfaces with other parts of the machine. In order to compensate the distortions, extra material is present in the critical areas to allow postwelding machining. The amount of extra material has to be optimized to reduce machining time and therefore the cost of the manufacturing. Thus, the evaluation of the welding-caused distortions is essential in order to confirm the extra-material strategy. In this scenario, an experimental and simulation campaign has been set up to predict the deformation of the TFCC during welding. First, welding coupons were welded in representative configurations. Then, these data were used to build a preliminary finite element method (FEM) model tool, using ANSYS software, which was then benchmarked against a "blind test" coupon and three TFCC-like mock-ups of 1-m length. Finally, a full FEM model was constructed using the previous outputs and is currently under assessment to predict the deformation of the TFCC during the welding process. This paper presents the numerical and experimental activities carried out so far, being EnginSoft S.p.A. the developer of FEM models, SIMIC S.p.A. the responsible of welding processes and data acquisition, and Fusion for Energy the contractual and technical supervisor.
ISSN:1051-8223
1558-2515
DOI:10.1109/TASC.2017.2782211