TY - GEN
T1 - Adaptability of optimization concept in the context of cryogenic distribution for superconducting magnets of fusion machine
AU - Sarkar, B.
AU - Bhattacharya, R.
AU - Vaghela, H.
AU - Shah, N.
AU - Choukekar, K.
AU - Badgujar, S.
PY - 2012
Y1 - 2012
N2 - Cryogenic distribution system (CDS) plays a vital role for reliable operation of large-scale fusion machines in a Tokamak configuration. Managing dynamic heat loads from the superconducting magnets, namely, toroidal field, poloidal field, central solenoid and supporting structure is the most important function of the CDS along with the static heat loads. Two concepts are foreseen for the configuration of the CDS: singular distribution and collective distribution. In the first concept, each magnet is assigned with one distribution box having its own sub-cooler bath. In the collective concept, it is possible to share one common bath for more than one magnet system. The case study has been performed with an identical dynamic heat load profile applied to both concepts in the same time domain. The choices of a combined system from the magnets are also part of the study without compromising the system functionality. Process modeling and detailed simulations have been performed for both the options using Aspen HYSYS®. Multiple plasma pulses per day have been considered to verify the residual energy deposited in the superconducting magnets at the end of the plasma pulse. Preliminary 3D modeling using CATIA® has been performed along with the first level of component sizing.
AB - Cryogenic distribution system (CDS) plays a vital role for reliable operation of large-scale fusion machines in a Tokamak configuration. Managing dynamic heat loads from the superconducting magnets, namely, toroidal field, poloidal field, central solenoid and supporting structure is the most important function of the CDS along with the static heat loads. Two concepts are foreseen for the configuration of the CDS: singular distribution and collective distribution. In the first concept, each magnet is assigned with one distribution box having its own sub-cooler bath. In the collective concept, it is possible to share one common bath for more than one magnet system. The case study has been performed with an identical dynamic heat load profile applied to both concepts in the same time domain. The choices of a combined system from the magnets are also part of the study without compromising the system functionality. Process modeling and detailed simulations have been performed for both the options using Aspen HYSYS®. Multiple plasma pulses per day have been considered to verify the residual energy deposited in the superconducting magnets at the end of the plasma pulse. Preliminary 3D modeling using CATIA® has been performed along with the first level of component sizing.
KW - Cryogenics distribution
KW - Superconducting magnet and dynamic heat-load
UR - http://www.scopus.com/inward/record.url?scp=84864764940&partnerID=8YFLogxK
U2 - 10.1063/1.4707134
DO - 10.1063/1.4707134
M3 - Conference contribution
AN - SCOPUS:84864764940
SN - 9780735410206
T3 - AIP Conference Proceedings
SP - 1951
EP - 1958
BT - Advances in Cryogenic Engineering - Transactions of the Cryogenic Engineering Conference-CEC
T2 - 2011 Joint Cryogenic Engineering and International Cryogenic Materials Conferences
Y2 - 13 June 2011 through 17 June 2011
ER -