Title :
AC Losses Analysis and Experiments of Superconducting Electromagnetic Iron Separator
Author :
Wenbin Ma ; Zhilong Hou ; Zhiyong Liu ; Feipeng Ning ; Guoqing Zhang ; Zian Zhu
Author_Institution :
State Key Lab. of Particle Detection & Electron., Inst. of High Energy Phys., Beijing, China
fDate :
6/1/2012 12:00:00 AM
Abstract :
A 3 T central field Superconducting Electromagnetic Iron Separator (SEIS), which was designed to separate dangerous ferromagnetic materials, such as detonators, from coal, has been successfully developed at Institute of High Energy Physics (IHEP). The SEIS magnet is mainly composed of a NbTi solenoid coil, a pair of binary current leads (CL) and a re-condensation cryostat with two GM cryocoolers (31 W/40 K, 1 W/4.2 K). Powered with a 250 A/50 V power supply, the magnet has 15 minutes of charging time and 20 minutes of discharging time. The AC losses, mainly consist of hysteretic loss and coupling loss, was calculated with a two-dimensional ANSYS FEA model. The effect of AC losses on the temperature distribution within the cold mass and its induced cryostat pressure rise were analysed during charging process. With regard to the cryostat pressure rise, the analysis results were quite close to the experimental results.
Keywords :
cryostats; ferromagnetic materials; finite element analysis; niobium alloys; superconducting coils; superconducting magnets; superconducting materials; temperature distribution; titanium alloys; AC losses analysis; GM cryocooler; NbTi; binary current leads; charging process; coal; cold mass; coupling loss; current 250 A; detonator; ferromagnetic material; hysteretic loss; induced cryostat pressure rise; recondensation cryostat; solenoid coil; superconducting electromagnetic iron separator; temperature distribution; time 15 min; two-dimensional ANSYS FEA model; voltage 50 V; Coils; Heating; Helium; Magnetic flux; Magnetic hysteresis; Magnetic separation; Superconducting magnets; AC loss; pressure rise; superconducting magnets; temperature margin;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2011.2178110
