Design, Fabrication, and Critical Current Testing of No-Insulation Superconducting Rotor Coils for NASA's 1.4 MW High-Efficiency Megawatt Motor

Scheidler, Justin J.; Tallerico, Thomas

doi:10.2514/6.2018-5002

Cited by 20 publications

(11 citation statements)

References 20 publications

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“…The preliminary design of the HEMM's superconducting rotor was detailed in [12] and [13]. Figure 1 depicts the current design of the superconducting rotor and Table 1 summarizes the notable characteristics.…”

Section: Summary Of the Design Of The Hemm's Rotormentioning

confidence: 99%

“…Although they were suggested only recently, a number of papers have reported the fabrication and critical current testing of no-insulation coils [13,14,16,17]. However, no-insulation coils have not been used in the rotor of an electric machine.…”

Section: Risk Reduction Testingmentioning

confidence: 99%

“…To reduce the risk that the HEMM's superconducting coils will be damaged by thermal stresses, a series of thermal cycling tests have been conducted on multiple sub-scale test coils. Prior work by the authors [13] discussed the coil fabrication and testing procedures and presented initial measurements of how two small, single-layer coils responded to repeated thermal cycling between room temperature and liquid nitrogen temperature (77 K). Here, that work is expanded by describing an improved coil fabrication procedure and by presenting thermal cycling measurements of two new sub-scale coils that have nearly all of the features of the full-scale HEMM coils.…”

Section: Risk Reduction Testingmentioning

confidence: 99%

“…After winding multiple sub-scale HTS coils using the authors' original coil fabrication process [13], the process was found to have a few deficiencies. The primary issue was that the geometry of the coils' end turns considerably deviated from the design; this resulted from the coil former's insufficient stiffness in some locations and the build up of a small amount of slack in the coil while winding.…”

Section: A Improved Coil Fabrication Proceduresmentioning

confidence: 99%

“…The testing procedure was the same as described in [13] except in the following ways. Here, the coils were given several minutes more time to warm up and were also given five minutes to cool down.…”

Section: B Thermal Cycling Testsmentioning

confidence: 99%

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Progress Toward the Critical Design of the Superconducting Rotor for NASA's 1.4~MW High-Efficiency Electric Machine

Scheidler

Tallerico

Miller

et al. 2019

AIAA Propulsion and Energy 2019 Forum

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NASA Glenn Research Center is developing a 1.4 MW high-efficiency electric machine for future electrified aircraft. This wound-field, synchronous machine employs a self-cooled, superconducting rotor to achieve excellent specific power and efficiency. This paper presents the progress made over the past year toward a critical design of the superconducting rotor, including refined analysis and risk reduction testing on prototype superconducting coils. A 3D finite element model of the rotor is developed to simulate the combined loading imposed by the initial cool down of the rotor from room temperature to cryogenic temperature and the subsequent rotation of the rotor up to the design speed. The model is evaluated to better predict the stress state in the critical components and the reduction in physical gap between the stator and rotor due to the resulting radial deflections. This model includes an enhanced model of the superconducting coil that considers the coil as an assembly of four individual coil layers. An improved coil fabrication process is described in detail. Two sub-scale test coils are fabricated and then tested under repeated thermal cycling between room temperature and liquid nitrogen temperature (77 K). It is demonstrated that the proposed coil fabrication procedure can produce no-insulation, high temperature superconducting coils that can survive several thermal cycles without apparent degradation.

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Section: Summary Of the Design Of The Hemm's Rotormentioning

confidence: 99%

Section: Risk Reduction Testingmentioning

confidence: 99%

Section: Risk Reduction Testingmentioning

confidence: 99%

Section: A Improved Coil Fabrication Proceduresmentioning

confidence: 99%

Section: B Thermal Cycling Testsmentioning

confidence: 99%

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Progress Toward the Critical Design of the Superconducting Rotor for NASA's 1.4~MW High-Efficiency Electric Machine

Scheidler

Tallerico

Miller

et al. 2019

AIAA Propulsion and Energy 2019 Forum

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Understanding quench in no-insulation (NI) REBCO magnets through experiments and simulations

Bhattarai

Kim

Radcliff

et al. 2020

Supercond. Sci. Technol.

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Present research on no-insulation (NI) rare earth barium copper oxide (REBCO) magnets have demonstrated their ability to produce high fields due to their compact nature. NI magnets have often been demonstrated to be self-protecting. However, evidence of mechanical damage in recent high field magnets, suggests that there are some issues about quench that must be resolved for this otherwise promising technology. This article attempts to explain multi-physics phenomena occurring during the quench of an NI magnet that can be used to elucidate quench behavior through experiments and simulations. A lumped circuit model is used for the circuit analysis where each coil is modeled as a single inductor with variable quench resistance in series and characteristic contact resistance in parallel. Three case studies have been analyzed: (1) a 3 double pancake (DP) standalone magnet, (2) a 2 DP coil in 31 T background, and (3) a high temperature superconductor/low temperature superconductor (HTS/LTS) hybrid user magnet that consists of a 13 T HTS insert and a 6 T LTS background magnet. Lessons learned from these analyses include: (1) characteristic resistance of NI coil rises during quench with the temperature rise; (2) influence of Hall effect exists on the voltage rise during quench; (3) over-current during quench can over-stress the coil; and (4) quench propagation from one end of the magnet generates significant unbalanced forces. This approach is expected to be used in the preliminary design of an ultra high field (>40 T) user magnet currently under design at the National High Magnetic Field Laboratory.

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A numerical method for spatially-distributed transient simulation to replicate nonlinear ‘defect-irrelevant’ behaviors of no-insulation HTS coil

Kim¹,

Musso²,

Bang³

et al. 2021

Supercond. Sci. Technol.

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This paper presents a numerical method, based on the partial element equivalent circuit (PEEC) technique, for spatially-distributed and time-varying simulation to analyze nonlinear ‘defect-irrelevant’ behaviors of a no-insulation (NI) high temperature superconductor (HTS) coil. We suggest a resistivity parameterization approach in combination of the PEEC method to replicate electromagnetic dynamics of an NI HTS coil containing multiple ‘defects.’ The proposed method is adopted to investigate ‘defect-irrelevant’ behaviors of an NI single pancake coil having lap joints as a form of artificial defects. To validate our approach, electromagnetic characteristics of the NI test coil are measured in a bath of liquid nitrogen at 77 K and compared with four key simulation results: (a) local voltages; (b) current distribution; (c) magnetic field; and (d) Joule heating distribution. Experimental measurements of local voltages and the magnetic field are compared to the simulation results to validate our numerical method.

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Design, Fabrication, and Critical Current Testing of No-Insulation Superconducting Rotor Coils for NASA's 1.4 MW High-Efficiency Megawatt Motor

Cited by 20 publications

References 20 publications

Progress Toward the Critical Design of the Superconducting Rotor for NASA's 1.4~MW High-Efficiency Electric Machine

Progress Toward the Critical Design of the Superconducting Rotor for NASA's 1.4~MW High-Efficiency Electric Machine

Understanding quench in no-insulation (NI) REBCO magnets through experiments and simulations

A numerical method for spatially-distributed transient simulation to replicate nonlinear ‘defect-irrelevant’ behaviors of no-insulation HTS coil

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