VIPER: an industrially scalable high-current high-temperature superconductor cable

Zachary Hartwig; R. Vieira; Brandon Sorbom; Rodney A. Badcock; M. Bajko; W. Beck; Bernardo Castaldo; Christopher Craighill; Mike Davies; J. Estrada; Vincent Fry; T. Golfinopoulos; A. Hubbard; J. Irby; S. Kuznetsov; Christopher J. Lammi; Philip C. Michael; Theodore Mouratidis; Richard A. Murray; A. Pfeiffer; Samuel Z. Pierson; Alexi Radovinsky; Michael D Rowell; Erica Salazar; Michael Segal; Peter W. Stahle; M. Takayasu; Thomas L Toland; Lihua Zhou

doi:10.1088/1361-6668/abb8c0

VIPER: an industrially scalable high-current high-temperature superconductor cable

Zachary Hartwig(Plasma Technology (United States)), R. Vieira(Plasma Technology (United States)), Brandon Sorbom(Boston Fusion (United States)), Rodney A. Badcock(Victoria University of Wellington), M. Bajko(European Organization for Nuclear Research), W. Beck(Plasma Technology (United States)), Bernardo Castaldo(European Organization for Nuclear Research), Christopher Craighill(Boston Fusion (United States)), Mike Davies(Victoria University of Wellington), J. Estrada(Plasma Technology (United States)), Vincent Fry(Plasma Technology (United States)), T. Golfinopoulos(Plasma Technology (United States)), A. Hubbard(Plasma Technology (United States)), J. Irby(Plasma Technology (United States)), S. Kuznetsov(Boston Fusion (United States)), Christopher J. Lammi(Boston Fusion (United States)), Philip C. Michael(Plasma Technology (United States)), Theodore Mouratidis(Plasma Technology (United States)), Richard A. Murray(Plasma Technology (United States)), A. Pfeiffer(Plasma Technology (United States)), Samuel Z. Pierson(Plasma Technology (United States)), Alexi Radovinsky(Plasma Technology (United States)), Michael D Rowell(Plasma Technology (United States)), Erica Salazar(Plasma Technology (United States)), Michael Segal(Boston Fusion (United States)), Peter W. Stahle(Plasma Technology (United States)), M. Takayasu(Plasma Technology (United States)), Thomas L Toland(Plasma Technology (United States)), Lihua Zhou(Plasma Technology (United States))

Superconductor Science and Technology

September 15, 2020

10.1088/1361-6668/abb8c0

Cited by 257Open Access

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Abstract

Abstract High-temperature superconductors (HTS) promise to revolutionize high-power applications like wind generators, DC power cables, particle accelerators, and fusion energy devices. A practical HTS cable must not degrade under severe mechanical, electrical, and thermal conditions; have simple, low-resistance, and manufacturable electrical joints; high thermal stability; and rapid detection of thermal runaway quench events. We have designed and experimentally qualified a vacuum pressure impregnated, insulated, partially transposed, extruded, and roll-formed (VIPER) cable that simultaneously satisfies all of these requirements for the first time. VIPER cable critical currents are stable over thousands of mechanical cycles at extreme electromechanical force levels, multiple cryogenic thermal cycles, and dozens of quench-like transient events. Electrical joints between VIPER cables are simple, robust, and demountable. Two independent, integrated fiber-optic quench detectors outperform standard quench detection approaches. VIPER cable represents a key milestone in next-step energy generation and transmission technologies and in the maturity of HTS as a technology.

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