DocumentCode
1481514
Title
Experimental characterization of resistive joints for use inside ATLAS toroids
Author
Volpini, Giovanni ; Baccaglioni, Giuseppe ; Pojer, Mirko
Author_Institution
LASA Labs., INFN, Segrate, Italy
Volume
11
Issue
1
fYear
2001
fDate
3/1/2001 12:00:00 AM
Firstpage
2130
Lastpage
2133
Abstract
The authors have investigated, both experimentally and theoretically, the thermo-electrical behavior of the ATLAS magnets resistive joints. These magnets exploit an Al-clad NbTi Rutherford superconducting cable, and the splices between different sections are performed by TIG-welding the Al matrices of the two cables to be connected. This technique is simple from a construction point of view, and we have shown that its performance is adequate for a safe operation of the magnets. The two main concerns during the design of these joints are the temperature rise due to Joule dissipation and the eddy currents induced under nonstationary conditions. We have devised a reliable model of these joints, that allows estimating their resistances and the induced eddy currents; later we have built and measured several sample joints to give experimental confirmation. The model requires, along with the joint geometry, the knowledge of the Rutherford-matrix interface resistance as well as the RRR of the aluminum matrix. In this paper we present the latest experimental data about the joint specific resistances, confirming the first results, and independent measurements of the interface resistance and Al RRR. All these quantities are characterized as a function of an applied magnetic field between 0 and 4 T
Keywords
aluminium; cable jointing; eddy currents; electric resistance; niobium alloys; superconducting cables; superconducting magnets; titanium alloys; 0 to 4 T; ATLAS magnets resistive joints; ATLAS toroids; Al-clad NbTi Rutherford superconducting cable; Joule dissipation; NbTi-Al; Rutherford-matrix interface resistance; TIG-welding; aluminum matrix; induced eddy currents; interface resistance measurement; joint specific resistances; nonstationary conditions; resistive joints; safe operation; splices; superconducting magnets; temperature rise; thermo-electrical behavior; Current measurement; Eddy currents; Electrical resistance measurement; Magnetic field measurement; Magnets; Niobium compounds; Solid modeling; Superconducting cables; Temperature; Titanium compounds;
fLanguage
English
Journal_Title
Applied Superconductivity, IEEE Transactions on
Publisher
ieee
ISSN
1051-8223
Type
jour
DOI
10.1109/77.920278
Filename
920278
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