Thermal Resistance Between Metallic Surfaces of Copper and Stainless Steel at Different Temperatures and Applied Forces for High Current HTS Cable-in-Conduit Conductors

High Temperature Superconductors are a promising option for many superconducting devices like high current conductors for large high-field magnets, current leads, or superconducting coils. Quench propagation in these devices is currently under intensive investigation, and it can be predicted by mode...

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Bibliographic Details
Published inIEEE transactions on applied superconductivity Vol. 32; no. 6; p. 1
Main Authors Bagrets, Nadezda, Heller, Reinhard, Weis, Johannes, Weiss, Klaus-Peter
Format Journal Article
LanguageEnglish
Published New York IEEE 01.09.2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Coils
Conductors
Contact resistance
Copper
Electric contacts
Electrical resistance measurement
Force measurement
Heat transfer
Heat transmission
High current
High temperature superconductors
Magnets
Material properties
Metal plates
Propagation
Stacks
Stainless steel
Stainless steels
Steel
Steel plates
Strain gauges
Superconducting devices
Superconductivity
Temperature measurement
Thermal conductivity
Thermal contact resistance
Thermal force
Thermal resistance
Thermodynamic properties
Thickness
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Summary:High Temperature Superconductors are a promising option for many superconducting devices like high current conductors for large high-field magnets, current leads, or superconducting coils. Quench propagation in these devices is currently under intensive investigation, and it can be predicted by modelling the entire structure. However, along with thermal material properties, the thermal properties of contact interfaces between structural ma-terials as well as electrical stabilizers are highly needed. So far, a lack of such data in the literature made the analysis of quench propagation very difficult. Thermal resistance of copper-copper and copper-stainless steel interfaces were characterized for different pressure and temper-ature ranges. Therefore, thermal conductivity was measured with the axial heat flow method within the Physical Property Measurement System of Quantum Design using Thermal Transport Option in the steady-state measurement mode in the temperature range from 4 K to 300 K. For the required investi-gation, the Thermal Transport Option was extended: the sample puck was equipped with an additional copper frame allowing measurement of the thermal conductance of a stack of metallic plates pressurized by a screw. The method was further extended to allow the measurement of thermal conductance at different applied force values. For this, the copper frame was equipped with strain gauges, and calibrated for measuring the force ap-plied to the stack at different temperatures. Further steps in-cluded the systematic measurement of thermal conductance ver-sus temperature of the stacks for a range of applied force values. Two copper stacks composed of copper plates of 100 m and 200 m of thickness, and one stack composed of copper and stainless steel plates of 100 m thickness were investigated. From the measured conductance values, the thermal contacts resistance between contacting materials was evaluated.
ISSN:1051-8223
1558-2515
DOI:10.1109/TASC.2022.3154327