Twisting Characteristics and Tensile Effects of a Quasi-Isotropic Strands Made of Coated Conductors

With the development of second generation (2G) high-temperature superconducting (HTS) tapes, several cabling configurations, such as twisting stacked-tapes cable and conductor on round core cables, have been proposed, and some prototypes were developed. Alternating current (ac) losses arise in HTS t...

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Veröffentlicht in:	IEEE transactions on applied superconductivity 2016-10, Vol.26 (7), p.1-4
Hauptverfasser:	Jiawei Li, Yinshun Wang, Han Zhang, Chenjie Shi, Jiping Xue, Hasegawa, Takayo
Format:	Artikel
Sprache:	eng
Schlagworte:	Coated conductor critical current Critical current density (superconductivity) Current measurement High-temperature superconductors Power cables quasi-isotropic strand Superconducting cables Temperature measurement Tensile stress twisting properties
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creator	Jiawei Li Yinshun Wang Han Zhang Chenjie Shi Jiping Xue Hasegawa, Takayo
description	With the development of second generation (2G) high-temperature superconducting (HTS) tapes, several cabling configurations, such as twisting stacked-tapes cable and conductor on round core cables, have been proposed, and some prototypes were developed. Alternating current (ac) losses arise in HTS tapes in ac operations, and those losses are an important consideration for applications since they influence the stability and operating cost. Conventionally, a twisting technique is used to effectively reduce the ac losses. This paper presents the twisting properties and tensile properties of a quasi-isotropic (QI) strand made from 2G tapes. The strand consists of 2G tapes, aluminum foil, and a metal sheath. A twisting apparatus was designed and demonstrated to research the characteristics of the strands in twisting situations. The critical currents and strain of a single CC were tested for different twist pitches in self-field and at 77 K. The results show that the critical twist pitch of the QI strand is higher than that of a single tape. The critical current of the QI strand was also measured at 77 K after the application of different tensile stresses at room temperature.
doi_str_mv	10.1109/TASC.2016.2587280
format	Article
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Alternating current (ac) losses arise in HTS tapes in ac operations, and those losses are an important consideration for applications since they influence the stability and operating cost. Conventionally, a twisting technique is used to effectively reduce the ac losses. This paper presents the twisting properties and tensile properties of a quasi-isotropic (QI) strand made from 2G tapes. The strand consists of 2G tapes, aluminum foil, and a metal sheath. A twisting apparatus was designed and demonstrated to research the characteristics of the strands in twisting situations. The critical currents and strain of a single CC were tested for different twist pitches in self-field and at 77 K. The results show that the critical twist pitch of the QI strand is higher than that of a single tape. 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Alternating current (ac) losses arise in HTS tapes in ac operations, and those losses are an important consideration for applications since they influence the stability and operating cost. Conventionally, a twisting technique is used to effectively reduce the ac losses. This paper presents the twisting properties and tensile properties of a quasi-isotropic (QI) strand made from 2G tapes. The strand consists of 2G tapes, aluminum foil, and a metal sheath. A twisting apparatus was designed and demonstrated to research the characteristics of the strands in twisting situations. The critical currents and strain of a single CC were tested for different twist pitches in self-field and at 77 K. The results show that the critical twist pitch of the QI strand is higher than that of a single tape. 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subjects	Coated conductor critical current Critical current density (superconductivity) Current measurement High-temperature superconductors Power cables quasi-isotropic strand Superconducting cables Temperature measurement Tensile stress twisting properties
title	Twisting Characteristics and Tensile Effects of a Quasi-Isotropic Strands Made of Coated Conductors
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