Comparing the thermal stability of NbTi and Nb<sub>3</sub>Sn wires

Breschi, Marco; Trevisani, Luca; Bottura, L.; Devred, A.; Trillaud, F.

doi:10.1088/0953-2048/22/2/025019

Cited by 16 publications

(7 citation statements)

References 17 publications

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“…Another important parameter for the assessment of the conductor performance is the minimum quench energy (MQE). Numerous experimental tests and numerical analyses of this parameter have been performed in the past both on individual strands [18,19] and cable in conduit conductors [20][21][22][23]. Selected results of the MQE tests performed on the Nb-Ti CPQS conductors of the ITER Project are reported here, showing the dependence of the MQE on the temperature margin with respect to the current sharing temperature of each conductor.…”

Section: Introductionmentioning

confidence: 99%

Performance analysis of the Nb−Ti conductor qualification samples for the ITER project

Breschi

Carati

Bessette

et al. 2015

Supercond. Sci. Technol.

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The ITER machine will require approximately 275 tons of Nb−Ti strands that will be used in poloidal field (PF) coils, correction coils (CC) and feeder busbars. The performance of all these conductors for the ITER machine is qualified by a short full-size sample (4 m) current sharing temperature (T cs ) test in the SULTAN facility at CRPP in Villigen, Switzerland, at the design operating current and peak field. Three ITER domestic agencies participated in PF conductor fabrication (China, the European Union, Russia) while the conductors for feeder busbars and correction coils are entirely produced by the Chinese domestic agency. Each conductor type was qualified by the ITER International Organization after reaching T cs values in excess of ITER specifications. This qualification enabled the launch of procurement and industrial production of the Nb−Ti cable-in-conduit conductors in each domestic agency. In this paper, we summarize the performance of the qualified Nb−Ti samples of the ITER Project, comparing strand performance with conductor performance. The details of the test results will be discussed in terms of dc performance, ac losses and minimum quench energies of each conductor type.

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Section: Introductionmentioning

confidence: 99%

Performance analysis of the Nb−Ti conductor qualification samples for the ITER project

Breschi

Carati

Bessette

et al. 2015

Supercond. Sci. Technol.

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“…For the high current densities that are present in the saturated strands the time constants may be too short for this assumption to be valid. It has been noted on the past that treating the strand elements in a homogenized way may not be accurate in certain strand stability regimes [9,23]. The copper in-between the embedded Nb3Sn filaments may have to be modelled as separate entity from the rest of the copper.…”

Section: Discussionmentioning

confidence: 99%

Effect of Strand Damage in Nb₃Sn Rutherford Cables on the Quench Propagation in Accelerator Magnets

Keijzer

Willering

Dhallé

et al. 2023

IEEE Trans. Appl. Supercond.

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Accelerator magnets employing Nb3Sn Rutherford cables are more susceptible to conductor degradation than Nb-Ti magnets. Recent measurements on a Nb3Sn accelerator magnet have revealed unexpected behaviour such as decaying voltages at constant current plateaus of V-I measurements, inverse ramp rate and temperature dependence of quench currents, and anomalous quench propagation measured by so-called quench antennas. Numerical modelling has shown that these anomalies can be explained by an inhomogeneous degradation in the Rutherford cable, in which a subset of strands is fully or partially degraded. In this paper, we study how this type of degradation can affect the early stages of quench propagation. With the aid of a network model, we show how quench antenna signals can be used to diagnose inhomogeneous conductor degradation in the Rutherford cable.

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“…Additionally, we allowed for current sharing rather than a sharp transition to fully normal state assumes an sharp transition from nucleate to film boiling while in reality a mixed boiling regime will exist across the temperature gradient and a more advanced analysis similar to that performed by Breschi et al for LHe will provide a more realistic picture near this discrepancy [30].…”

Section: Comparison Of Theory and Experimentsmentioning

confidence: 99%

Quench and stability of Roebel cables at 77 K and self-field: Minimum quench power, cold end cooling, and cable cooling efficiency

et al. 2018

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A 9-tape, 14 mm wide ReBCO Roebel cable was soldered onto a U-shaped holder. The critical current, Ic, was measured at 77 K and self-field. The cryostability of the cable was studied in response to the application of local pulses of 1 to 14 W at several values of i = I/Ic. A detailed analysis of the cable's cryostability was presented. With a Stekly parameter α = G/Q « 1 and a heat generation margin of ~190 kW/m 2 the present ReBCO cable was shown to be ultra cryostable with respect to internally generated transport-current overload. However, the cable was much less stable against externally and locally applied disturbances because of the tendency to initiate local film boiling. A locally applied 10 W led to a prediction of a film-boiling-cooled zone with a temperature of 181 K. However, when cold-end cooling was considered, the predicted hot spot temperature decreased to 87-115 K depending on the surface-cooling efficiency. Predictions were compared to experiment extracting a cooling efficiency parameter representing the penetration of the cryogen into the cable. Experiment showed the generation of time stable normal zones which were a function of disturbance power. This led to the description of the cable stability in terms of minimum quench power; the results are presented in stability diagrams.

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Comparing the thermal stability of NbTi and Nb₃Sn wires

Cited by 16 publications

References 17 publications

Performance analysis of the Nb−Ti conductor qualification samples for the ITER project

Performance analysis of the Nb−Ti conductor qualification samples for the ITER project

Effect of Strand Damage in Nb₃Sn Rutherford Cables on the Quench Propagation in Accelerator Magnets

Quench and stability of Roebel cables at 77 K and self-field: Minimum quench power, cold end cooling, and cable cooling efficiency

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Comparing the thermal stability of NbTi and Nb3Sn wires

Cited by 16 publications

References 17 publications

Performance analysis of the Nb−Ti conductor qualification samples for the ITER project

Performance analysis of the Nb−Ti conductor qualification samples for the ITER project

Effect of Strand Damage in Nb3Sn Rutherford Cables on the Quench Propagation in Accelerator Magnets

Quench and stability of Roebel cables at 77 K and self-field: Minimum quench power, cold end cooling, and cable cooling efficiency

Contact Info

Product

Resources

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Comparing the thermal stability of NbTi and Nb₃Sn wires

Effect of Strand Damage in Nb₃Sn Rutherford Cables on the Quench Propagation in Accelerator Magnets

Quench and stability of Roebel cables at 77 K and self-field: Minimum quench power, cold end cooling, and cable cooling efficiency