Report from Session 2 Main Dipoles. P. McIntyre 2005 – 24T ss Tripler, a lot of Bi-2212, Je = 800 A/mm2 E. Todesco 2010 20 T, 80% ss 30% NbTi 55 %NbSn.

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Presentation transcript:

Report from Session 2 Main Dipoles

P. McIntyre 2005 – 24T ss Tripler, a lot of Bi-2212, Je = 800 A/mm2 E. Todesco T, 80% ss 30% NbTi 55 %NbSn 15 %HTS All Je < 400 A/mm2

Conductor NbSn: T (80% ss !!) – Developed, existing in moderastre quantities (tons); for ITER (less Jc) 400 tons – Needs improvement in mechanical, stability – Instability is an issue but we can manage – A reduction 2 in – projected- cost is an asset – 2 manufacturers only: 1 at good level, 1 near

Bi-2212 I c =348 A I c =186 A I c =438 A I c =488 A Without insulation With insulation Coil section 1Coil section 2 Short samples HTS (Bi-2212): needed for B > 16 T (at 80%) 40% cost of material for 20% field Je = A/mm2 today; difficult material; HEP is almost only client… Either a strong program or very likely to be abandoned Key step!

YBCO YBCO: may be a great hope: many developers Cost is –still- stellar Lack of multikA compact cable may be a killer… The many developers guidfed by othertr applications (Power, electrical devices…) If we want gain we need to choose between Bi-2212 and Ybco, then push and guide development

New ideas needed… what do they need to be developed? We might go far to eliminate all of these problems if we could fully texture the powder in the subelements: But how to do it? 6 mm

Magnet Development Chart

LBL:16 T reached with bladder system… “common-coil”“cos-theta”“block” 13.8T, mm bore 14.5T, T, 2003

Adding a bore… HD2: 43 mm bore 4.2 K : 15.6 T

Extensive investigation of superconductor and classical structure PIT Models: B max (100% of SSL). RRP-108/127 coil: B max = K (97% of SSL) instabilities at ~21kA

Conclusion from NbSn US FERMI 20 dipole and 35 quadrupole 1-m long coils Reasonable size reproducibility Short fabrication time 2 dipole and 14 quadrupole 4-m long coils From CORE programs + LARP 11 T in dipoles and quadrupoles: we can count on it (but development on conductor and structure still needed…) T in view, but 3 years needed…

Getting acquainted with HTS in special applications: BNL We have successfully designed, built and tested a large number of HTS coils and magnets: – Number of HTS coils built: ~100 – Number of magnet structures built and tested: ~10 We are performing HTS magnet R&D on a wide range of programs: – High T, low B (several, in house) – Medium T, medium B (3 funded programs) – Low T, high B (>20 T, 2 funded programs) FRIB Main coil: layer wound Bucking: double pancake YBCO: 25 T – 100 mm solenoids for SMES…

KEK : Nb 3 Al and more… Nb 3 Sn Compressive Load

Europe: Fresca-2 (2013) Making a detailed 3D model is important: the devil is in the detail 3D turn by turn model

Hot points… Radiation facility CERN) Design : for B>13-14 T consensus toward block design. Proved ? Not yet! Aperture: needs more than educated guess (small aperture favor block vs cos ) CONDUCTOR – Is the performance driver – Is the cost driver – 20 T: 4 G(CHF-$-€) Mitigation measure: T range Assess real margin (80%, 90%?) Needs to drive (and finance) development: Ybco > Bi-2212 HL-LHC (11 T DS dipole, IR 13 T) is a valid test bed Other specific issues: protection & powering, stress management, small aperture, two-in-one design

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