%0 Journal Article %1 SavoldiRichard2010167 %A Richard, L. Savoldi %A Casella, F. %A Fiori, B. %A Zanino, R. %D 2010 %J Cryogenics %K 2010 Modelica cryogenics helium %N 3 %P 167 - 176 %R 10.1016/j.cryogenics.2009.07.008 %T The 4C code for the cryogenic circuit conductor and coil modeling in ITER %U http://dx.doi.org/10.1016/j.cryogenics.2009.07.008 %V 50 %X A new tool – the 4C code – has been developed, which allows the thermal-hydraulic simulation of the entire superconducting magnet system of the International Thermonuclear Experimental Reactor (ITER), with particular reference to: (1) the winding made of cable-in-conduit conductors (CICC), (2) the structures (the radial plates and the case of the toroidal field – TF – coils, for instance) and (3) the cooling circuits. In this paper the different components of the 4C code (1D 2-channel model of the CICC and of the structure cooling channels, 2D model of selected cross sections of the structures, 0D/1D model of the cryogenic circuit) are described in detail, together with the strategy adopted for the coupling between the different components and their integration in a single tool. The new tool is then applied to the modeling of two transients in an ITER TF coil: a simplified version of a cooldown of the coil and the response to a heat pulse applied in the winding.

@article{SavoldiRichard2010167, abstract = {A new tool – the 4C code – has been developed, which allows the thermal-hydraulic simulation of the entire superconducting magnet system of the International Thermonuclear Experimental Reactor (ITER), with particular reference to: (1) the winding made of cable-in-conduit conductors (CICC), (2) the structures (the radial plates and the case of the toroidal field – TF – coils, for instance) and (3) the cooling circuits. In this paper the different components of the 4C code (1D 2-channel model of the CICC and of the structure cooling channels, 2D model of selected cross sections of the structures, 0D/1D model of the cryogenic circuit) are described in detail, together with the strategy adopted for the coupling between the different components and their integration in a single tool. The new tool is then applied to the modeling of two transients in an ITER TF coil: a simplified version of a cooldown of the coil and the response to a heat pulse applied in the winding.}, added-at = {2013-01-07T16:50:55.000+0100}, author = {Richard, L. Savoldi and Casella, F. and Fiori, B. and Zanino, R.}, biburl = {https://www.bibsonomy.org/bibtex/27f44ff08b7b6c75f3fe7a75a20b77be0/thorade}, description = {ScienceDirect.com - Cryogenics - The 4C code for the cryogenic circuit conductor and coil modeling in ITER}, doi = {10.1016/j.cryogenics.2009.07.008}, interhash = {f95368a0ba300c26c608df9a84988d3f}, intrahash = {7f44ff08b7b6c75f3fe7a75a20b77be0}, issn = {0011-2275}, journal = {Cryogenics}, keywords = {2010 Modelica cryogenics helium}, note = {CHATS on Applied Superconductivity Workshop 2008}, number = 3, pages = {167 - 176}, timestamp = {2013-01-07T17:16:15.000+0100}, title = {The 4C code for the cryogenic circuit conductor and coil modeling in ITER}, url = {http://dx.doi.org/10.1016/j.cryogenics.2009.07.008}, volume = 50, year = 2010 }