Transverse stress effects in ITER conductors

Joel H. Schultz; Luisa Chiesa; David L. Harris; Peter J. Lee; Joseph V. Minervini; Ben J. Senkowicz; Makoto Takayasu; Peter Titus

doi:10.1109/TASC.2005.849092

Transverse stress effects in ITER conductors

Joel H. Schultz, Luisa Chiesa, David L. Harris, Peter J. Lee, Joseph V. Minervini, Ben J. Senkowicz, Makoto Takayasu, Peter Titus

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

The International Thermonuclear Experimental Reactor (ITER) Central Solenoid and Toroidal Field Model Coils (CSMC, TFMC) and the CSMC Insert Coils using Nb₃₃Sn had unexpectedly low current-sharing temperatures and cable "n-values." This paper argues that the anomalous effects can be explained by the high longitudinal strain due to transverse Lorentz loads. Simulated results of earlier experiments with A15 monoliths indicate that the transverse stress "multiplier" is actually a longitudinal strain multiplier due to transverse loading. Irreversible cyclic degradation effects in the cables with the lowest thermal contraction mismatches are explained by showing that a modest precompression is required to prevent tensile cracking of a significant number of individual filaments. Examination of filament breakage due to bending shows the possibility of a well-defined threshold for irreversible damage.

Original language	English (US)
Pages (from-to)	1371-1374
Number of pages	4
Journal	IEEE Transactions on Applied Superconductivity
Volume	15
Issue number	2 PART II
DOIs	https://doi.org/10.1109/TASC.2005.849092
State	Published - Jun 2005
Externally published	Yes

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Electrical and Electronic Engineering

Keywords

ITER
Nb3Sn
Strain control
Superconductor

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10.1109/TASC.2005.849092

Cite this

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title = "Transverse stress effects in ITER conductors",

abstract = "The International Thermonuclear Experimental Reactor (ITER) Central Solenoid and Toroidal Field Model Coils (CSMC, TFMC) and the CSMC Insert Coils using Nb33Sn had unexpectedly low current-sharing temperatures and cable {"}n-values.{"} This paper argues that the anomalous effects can be explained by the high longitudinal strain due to transverse Lorentz loads. Simulated results of earlier experiments with A15 monoliths indicate that the transverse stress {"}multiplier{"} is actually a longitudinal strain multiplier due to transverse loading. Irreversible cyclic degradation effects in the cables with the lowest thermal contraction mismatches are explained by showing that a modest precompression is required to prevent tensile cracking of a significant number of individual filaments. Examination of filament breakage due to bending shows the possibility of a well-defined threshold for irreversible damage.",

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T1 - Transverse stress effects in ITER conductors

AU - Schultz, Joel H.

AU - Chiesa, Luisa

AU - Harris, David L.

AU - Lee, Peter J.

AU - Minervini, Joseph V.

AU - Senkowicz, Ben J.

AU - Takayasu, Makoto

AU - Titus, Peter

PY - 2005/6

Y1 - 2005/6

N2 - The International Thermonuclear Experimental Reactor (ITER) Central Solenoid and Toroidal Field Model Coils (CSMC, TFMC) and the CSMC Insert Coils using Nb33Sn had unexpectedly low current-sharing temperatures and cable "n-values." This paper argues that the anomalous effects can be explained by the high longitudinal strain due to transverse Lorentz loads. Simulated results of earlier experiments with A15 monoliths indicate that the transverse stress "multiplier" is actually a longitudinal strain multiplier due to transverse loading. Irreversible cyclic degradation effects in the cables with the lowest thermal contraction mismatches are explained by showing that a modest precompression is required to prevent tensile cracking of a significant number of individual filaments. Examination of filament breakage due to bending shows the possibility of a well-defined threshold for irreversible damage.

AB - The International Thermonuclear Experimental Reactor (ITER) Central Solenoid and Toroidal Field Model Coils (CSMC, TFMC) and the CSMC Insert Coils using Nb33Sn had unexpectedly low current-sharing temperatures and cable "n-values." This paper argues that the anomalous effects can be explained by the high longitudinal strain due to transverse Lorentz loads. Simulated results of earlier experiments with A15 monoliths indicate that the transverse stress "multiplier" is actually a longitudinal strain multiplier due to transverse loading. Irreversible cyclic degradation effects in the cables with the lowest thermal contraction mismatches are explained by showing that a modest precompression is required to prevent tensile cracking of a significant number of individual filaments. Examination of filament breakage due to bending shows the possibility of a well-defined threshold for irreversible damage.

KW - ITER

KW - Nb3Sn

KW - Strain control

KW - Superconductor

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ER -

Transverse stress effects in ITER conductors

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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