Design of a 60 kA Flux Pump for Fusion Toroidal Field Coils

Rice, James H.P.; Geng, Jianzhao; Bumby, Chris W.; Weijers, H.W.; Wray, S.; Zhang, Heng; Schoofs, Frank; Badcock, Rodney A.

doi:10.1109/tasc.2021.3137762

Cited by 13 publications

(7 citation statements)

References 37 publications

(38 reference statements)

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“…Operation at low temperatures would require very large current leads, but these current-ratings are not unrealistic for a high-field facility. An alternative approach is to supply the current using an HTS flux pump [30][31][32][33][34][35].…”

Section: Model Resultsmentioning

confidence: 99%

A proof-of-concept Bitter-like HTS electromagnet fabricated from a silver-infiltrated (RE)BCO ceramic bulk

Taylor,

Weijers,

Ainslie

et al. 2024

Supercond. Sci. Technol.

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A novel concept for a compact high-field magnet coil is introduced. This is based on stacking slit annular discs cut from bulk (RE)BCO ceramic in a Bitter-like architecture. Finite-element modelling shows that a small 20-turn stack (with a total coil volume of <20 cm3) is capable of generating a central bore magnetic field of >2 T at 77 K and >20 T at 30 K. Unlike resistive Bitter magnets, the HTS Bitter stack exhibits significant non-linear field behaviour during current ramping, caused by current filling proceeding from the inner radius outwards in each HTS layer. Practical proof-of-concept for this architecture was then demonstrated through fabricating an uninsulated 4-turn prototype coil stack and operating this at 77 K. A maximum central field of 0.382 T was measured at 1.2 kA, with an accompanying 6.1 W of internal heat dissipation within the coil. Strong magnetic hysteresis behaviour was observed within the prototype coil, with ≈30% of the maximum central field still remaining trapped 45 min after the current had been removed. The coil was thermally stable during a 15 min hold at 1 kA, and survived thermal cycling to room temperature without noticeable deterioration in performance. A final test-to-destruction of the coil showed that the limiting weak point in the stack was growth-sector boundaries present in the original (RE)BCO bulk.

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Section: Model Resultsmentioning

confidence: 99%

A proof-of-concept Bitter-like HTS electromagnet fabricated from a silver-infiltrated (RE)BCO ceramic bulk

Taylor,

Weijers,

Ainslie

et al. 2024

Supercond. Sci. Technol.

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“…This may cause excessive heating, and unintentionally damage the switch. Additionally, it was recently shown that the power efficiency of flux-flow HTS transformer-rectifier flux pumps is improved by the ratio of the self-field to the applied magnetic field critical current κ = I c0 /I c (B a p p,⊥ ) [26]. In this case, the reduction of I c0 is expected to have a direct impact on the power efficiency of the device.…”

Section: Implications For Hts Switchesmentioning

confidence: 99%

“…Secondly, I c influences AC magnetic field switching, as the threshold field B th,⊥ decreases with larger fractions of I t /I c0 [16]. Finally, I c alters flux flow resistance by decreasing the current at which voltage is generated, while also limiting the power efficiency of switching [26]. Thus, understanding the critical current behavior of HTS switching elements using iron-core electromagnets is important for HTS flux-pump design.…”

Section: Introductionmentioning

confidence: 99%

Critical current asymmetry in HTS switches using iron-core electromagnets

Rice¹,

Taylor²,

Moseley³

et al. 2022

Supercond. Sci. Technol.

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Iron-core electromagnets are used widely as applied-field switches in HTS flux pumps. It was recently reported that the critical current (I c) of the HTS wire is suppressed by up to 45% in the air-gap of the iron-core. Here, it is reported that the self-field I c of a single tape (unifilar) is suppressed from 357 A to 195 A while in the air-gap of the iron-core, agreeing closely with the previous study. This is extended by showing the I c response to perpendicular magnetic field is asymmetric, with peak I c of 249 A found to be at 0.16 T of applied field. This effect can be eliminated using an anti-parallel current configuration (bifilar), which is shown experimentally to recover close to the no-core self-field I c of 357 A with no observed asymmetry. The results of both types of switch configuration are closely replicated in finite-element modelling using COMSOL Multiphysics®. This is caused by the asymmetric interaction between the self-induced magnetic field of the HTS switch element and the magnetic circuit of the iron-core electromagnet.

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“…Applications like flux pumping require relatively low voltage so it rules out electrical breakdown potential risk. For example, to charge the load coil of 60kA in 24 hour, a dc voltage of 55mV is required and only 6mV is needed to maintain a long-term steady current of 60kA [29].…”

Section: B Non-inductive Winding Structurementioning

confidence: 99%

A Noninductive Bifilar Coil to Design Compact Flux Pumps for HTS Magnets

Iftikhar

Geng

Yuan

et al. 2022

IEEE Trans. Appl. Supercond.

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High temperature superconducting flux pump is a promising way of energizing superconducting magnets without direct electrical contacts. It can remove the resistive heating and heat leakage from the current leads at room temperature. It is well known that applying the current over the critical current of the superconductor, will force the superconducting layer to enter into the flux flow regime. This flux flow resistivity generates a dc voltage across the length of the HTS tape. This phenomenon is well understood , however, it is difficult to generate a high dc charging voltage without a high current. In this work, we demonstrate a novel flux pumping technique by using a noninductive bifilar bridge wound in parallel to the HTS coil. This configuration can generate large dc voltages using relatively small currents. It results in effectively pumping dc currents equal to the critical current for large HTS magnets.

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Design of a 60 kA Flux Pump for Fusion Toroidal Field Coils

Cited by 13 publications

References 37 publications

A proof-of-concept Bitter-like HTS electromagnet fabricated from a silver-infiltrated (RE)BCO ceramic bulk

A proof-of-concept Bitter-like HTS electromagnet fabricated from a silver-infiltrated (RE)BCO ceramic bulk

Critical current asymmetry in HTS switches using iron-core electromagnets

A Noninductive Bifilar Coil to Design Compact Flux Pumps for HTS Magnets

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