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Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 1LTHFSW10
Quench Protection
in HTS Magnets
Ramesh Gupta, BNL
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 2LTHFSW10
Overview
• BNL Experience
– We have built a large number of coils with all HTS (Bi2212, Bi2223, MgB2, 2G). We can see the differences between coils made with different conductors.
– Brief review of the test results of 2G coils
• BNL Program
– We have started a systematic R&D
– Brief overview of our plans
Protection issue is high on priority list for SMES program.
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 3LTHFSW10
Low Temp Performance of FRIB Coils(R&D during technology development period)
050
100150200250300350400450500550600
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
I c, A
(0.1
µV
/cm
)
Temp (K)
ASC YBCO Coil (with nano-dots)
SP YBCO Coil (without doping)
ASC BSCCO Coil (1st series)
ASC YBCO Coil
ASC Bi2223
SP YBCO Coil
During the initial FRIB R&D period, coils with 2G HTS from ASC (~0.4 mm X 0.3 mm) and SuperPower (0.4 mm X 0.1 mm) were built and tested
Constructed with the conductor purchased ~ 3 years ago
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 4LTHFSW10
Low Temp Performance of FRIB Coils(R&D during technology development period)
ASC YBCO Coil (with nano-dots)SP YBCO Coil (without doping) ASC BSCCO Coil (1st series)
0100200300400500600700800900
10001100120013001400
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90Temp (K)
J e, A
/mm
2 (0.1
µV/
cm)
ASC YBCO Coil
ASC Bi2223 Coil
SPYBCO Coil
These numbers are amazing ...• May be too demanding for protection and should be avoided in real applications.
Tape width: ~ 4 mm; Length used in single coil ~100 meterCopper thickness: SuperPower ~ 0.045 mm; ASC ~ 0.1 mm
If coils to go normal (quench, thermal runaway, etc.):
• Copper current density in ASC coil : ~1500 A/mm2
• Copper current density in SuperPower coil : ~3000 A/mm2
Coil remained protected@(we usually don’t allow such
high Jcu in LTS magnets)
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 5LTHFSW10
Low Temperature (4K) High Current Coil Tests
0
50
100
150
200
250
300
350
400
450
0 20 40 60 80 100
Temperature (K)
I c (0
.1µV
/m)
8B9A9A extrapolated2A interpolated2B
double coil #2
double coil #1
Note: ~10 T or ~20 T design needs only 220 A with SuperPower Tape
• Are these high current tests too demanding in terms of protection?• Were we too lucky or spoiled by initial FRIB tests to ~ 600 A? • Do we need more copper for protection (reduce Je) for high currents?
Cu current density @220 A : ~1200 A/mm2
These high currents are possible only at low fields (fewer coils) and may not be a concern of PBL/BNL 10 T solenoid. Also amount of Cu may be OK. But it certainly raises flag.
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 6LTHFSW10
Things may work well when everything is perfect (conductor, coil construction, etc.). But sometime, things are not perfect.
• What happens when there is a local irregularity in coil because of – variation coil construction
– variation in particular component of the conductor
– local disturbances, environment
– or, whatever
• A local irregularity may turn into permanent defect under demanding circumstances of high current and high fields, made possible by 4K operation of HTS.
• We must protect coils in all cases.
Experience from 2G Coil Tests
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 7LTHFSW10
We need to approach this issue from two directions:• Magnet technology What can be done in the magnet technology to protect the coil despite some irregularities?
• Conductor TechnologyWhat can be done to make conductor more robust? This issue has been found to be less problematic in 1G than in 2G
Most likely, a solution will involve a combination of the two.Remember, it may be an issue specific to high field magnets. So we (magnet builder and conductor manufacturer) have to work together to find a workable solution.
Approach
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 8LTHFSW10
Near Term HTS Quench R&D Plans at BNL
• Systematic R&D with small coils
• Study quench propagation velocity in different conditions
(temperature, field)
• Improve electronics for detecting small voltage signal over noise
• Increase instrumentation for protecting coil
• Quench protection is a high priority issue in SMES Program
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 9LTHFSW10
Variety of HTS Coils
Large, small, single pancake, circular, double pancake, bi-filar
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 10LTHFSW10
Development of Quick-turn-around Low Noise Structure/Electronics
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 11LTHFSW10
Conductor Test in Background Field
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 12LTHFSW10
Double pancake coils in structure is given to
electrical engineers to develop quench detection
and protection electronics.
Sacrificing these coils is tolerated to study the limits
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 13LTHFSW10
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 14LTHFSW10
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 15LTHFSW10
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 16LTHFSW10
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 17LTHFSW10
Experimental R&D with Test Coils(need to build and test many coils)
Large coils: ~100 meter wire(test proven theory)
Small coils: ~10 meter tape(we can afford to sacrifice them to understand the limit)
Superconducting Magnet Division
R. Gupta, BNL, Quench Protection in HTS Magnets, Monterey, CA, November 10, 2010 Slide No. 18LTHFSW10
We need to approach this issue from two directions:• Magnet technology What can be done in the magnet technology to protect the coil despite some irregularities?
• Conductor TechnologyWhat can be done to make conductor more robust? This issue has been found to be more challenging in 2G than it was in 1G for a variety of reasons
Most likely, a solution will involve a combination of the two.Remember, it may be an issue specific to high field magnets. So we (magnet builder and conductor manufacturer) have to work together to find a workable solution.
Summary : Approach
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