Federico Scurti scite author profile

High temperature superconducting materials are the only option for the generation of magnetic fields exceeding 25 T and for magnets operating over a broad range of temperature and magnetic field for power applications. One remaining obstacle for the implementation of high temperature superconductors magnets into systems, however, is the inability to rapidly detect a quench. In this letter we present a novel quench detection technique that has been investigated experimentally. Optical fibers are co-wound into two small Bi2Sr2Ca2Cu3O10+x superconducting coils and interrogated by Rayleigh-backscattering. Two different configurations are used, one with the fiber atop the conductor and the other with the fiber located as turn-to-turn insulation. Each coil is also instrumented with voltage taps (VTs) and thermocouples for comparison during heater-induced quenches. The results show that Rayleigh-backscattering interrogated optical fibers (RIOF) have significant advantages over traditional techniques, including very high spatial resolution and the ability to detect a hot-spot well before the peak local temperature exceeds the current sharing temperature. Thus, RIOF quench detection is intrinsically faster than VTs, and this intrinsic advantage is greater as the coil size and/or current margin increases.

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CORC^® wires containing integrated optical fibers for temperature and strain monitoring and voltage wires for reliable quench detection

Laan

Weiss

Scurti

et al. 2020

Supercond. Sci. Technol.

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Safe operation of large superconducting magnets wound from high-temperature superconductors (HTS) requires reliable detection of the onset of a quench. A novel method to integrate optical fibers and voltage wires within the core of multi-tape HTS CORC ® wires has been developed that allows real time monitoring of local changes in strain, temperature and of the superconducting state of the magnet windings. The ability to detect highly localized changes in temperature with Rayleigh scattering in the embedded optical fibers provides invaluable information about local heating at hot spots from which a quench may originate. Integrated voltage contacts allow accurate voltage measurements in long CORC ® wires without being affected by high current ramp rates or electromagnetic interference. They also allow detection of inductively driven redistribution of current between tapes in CORC ® wires that may occur at high current ramp rates. Continuous monitoring of temperature and voltage was used to detect the formation of local hot spots induced by a heater or by operating the CORC ® wire above its critical current. The results show that, within the boundary conditions of the experiment and the method by which the optical fibers were integrated into the CORC ® wire in this study, the speed and resolution with which hot spots can be detected with optical fibers lagged that of the integrated voltage wires. This study also shows that integrated voltage wires reliably detected the formation of a local hot spot in a 5.1 meter long coiled CORC ® wire, down to a hot spot size covering 0.1% of the conductor length and at current ramp rates as high as 2000 A s −1 . Voltage measurements thus remain an effective option for quench detection in magnets wound with HTS conductors for which current sharing between tapes allows for operation within the flux flow regime.

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SMART conductor on round core (CORC^®) wire via integrated optical fibers

Scurti¹,

Weiss²,

Laan³

et al. 2021

Supercond. Sci. Technol.

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Superconducting cables based on high temperature superconductors (HTS) are necessary for applications requiring large currents and low inductance, such as compact fusion reactors. In this paper, we report the proof-of-concept of a SMART Conductor on Round Core (CORC®) wire realized via integration of optical fibers into the copper core. A SMART CORC® wire with integrated optical fibers was manufactured and its capabilities have been experimentally demonstrated. Results show that by interrogating the optical fibers via Rayleigh backscattering, a Spectral Shift signal as a function of time and position along the cable can be used to detect and locate hot-spots that are developed within the wire or its terminations. It has been found that highly localized current injection into the terminations could initiate hot-spots within the cable at locations where current redistribution between tapes occur. This effect is virtually eliminated when adequate current connections are used that inject current evenly along the cable terminations. Normal zone propagation velocities have been calculated as a function of time using Spectral Shift data for a heater-induced quench as well as a quench induced by overcurrent. In both cases the normal zone propagation velocity was about 6 cm s−1, but in the heater-induced experiment it was preceded by 500 ms of slower propagation at 2.5 cm s−1.

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Self-monitoring ‘SMART’ (RE)Ba₂Cu₃O_7−xconductor via integrated optical fibers

Scurti

Sathyamurthy

Rupich

et al. 2017

Supercond. Sci. Technol.

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A self-monitoring, SMART (RE)Ba2Cu3O7−x (REBCO) conductor has been created by integrating optical fibers into the solder fillet of the current REBCO conductor architecture. By interrogating the integrated optical fiber by Raleigh backscattering, a spectral shift signal as a function of time and position along the conductor is obtained. Due to the direct integration into the solder fillet, intimate, consistent contact between fiber and conductor is obtained, while the optical fiber is protected and does not take up any space in the magnet winding. Therefore, the SMART conductor enhances the benefits of the co-wound fiber approach and provides ultimate sensitivity and practicality. Several samples of SMART REBCO conductor have been manufactured and characterized. The strain self-sensing capabilities have been demonstrated as well as thermal perturbation detection and localization with 2.56 mm spatial resolution. Results show that a key feature of the SMART conductor concerns its sensitivity to thermal perturbation; unlike in the case of a coil with co-wound optical fiber, the SMART REBCO sensitivity increases as the temperature decreases. A series of quench measurements have been performed, both on straight samples and on a pancake coil, at temperatures as low as 14.6 K. Using the data collected by the SMART REBCO during quench experiments, the temporal evolution of the size of a normal zone and the instantaneous normal zone propagation velocity have been calculated.

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Effects of metallic coatings on the thermal sensitivity of optical fiber sensors at cryogenic temperatures

Scurti

McGarrahan

Schwartz

2017

Opt. Mater. Express

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Federico Scurti

Quench detection for high temperature superconductor magnets: a novel technique based on Rayleigh-backscattering interrogated optical fibers

CORC^® wires containing integrated optical fibers for temperature and strain monitoring and voltage wires for reliable quench detection

SMART conductor on round core (CORC^®) wire via integrated optical fibers

Self-monitoring ‘SMART’ (RE)Ba₂Cu₃O_7−xconductor via integrated optical fibers

Effects of metallic coatings on the thermal sensitivity of optical fiber sensors at cryogenic temperatures

Contact Info

Product

Resources

About

Federico Scurti

Quench detection for high temperature superconductor magnets: a novel technique based on Rayleigh-backscattering interrogated optical fibers

CORC® wires containing integrated optical fibers for temperature and strain monitoring and voltage wires for reliable quench detection

SMART conductor on round core (CORC®) wire via integrated optical fibers

Self-monitoring ‘SMART’ (RE)Ba2Cu3O7−xconductor via integrated optical fibers

Effects of metallic coatings on the thermal sensitivity of optical fiber sensors at cryogenic temperatures

Contact Info

Product

Resources

About

CORC^® wires containing integrated optical fibers for temperature and strain monitoring and voltage wires for reliable quench detection

SMART conductor on round core (CORC^®) wire via integrated optical fibers

Self-monitoring ‘SMART’ (RE)Ba₂Cu₃O_7−xconductor via integrated optical fibers