Outline: Goals for the cable development at CERN. Main parameters of the cable. Cable development work for a cable width of 15.1 mm and for a cable width.

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Presentation transcript:

Outline: Goals for the cable development at CERN. Main parameters of the cable. Cable development work for a cable width of 15.1 mm and for a cable width of 14.7 mm. Future cable development work. Cable development at CERN for the 11 T dipole Luc Oberli

Goals for the cable development at CERN Optimization of the cable parameters for a cable made either with RRP or PIT strands in order to minimize the Ic degradation and to get a cable mechanically stable for winding. Determination of the cabling parameters to fabricate a cable with a core (not addressed up to now).

Main parameters of the cable Width15.1 mm14.7 mm Number of strands40 Mid-thickness1.269 mm Thin edge1.165 mm1.168 mm Thick edge1.373 mm1.370 mm Keystone angle0.79 o t/2d thin edge83.2 %83.4 % t/2d thick edge98.1 %97.8 % Compaction factor83.9 %86 % Transposition pitch100 mm

The keystoned cables are made at CERN in one pass. 7 cabling runs performed to optimize the cable parameters. Hard copper wires of 0.7 mm nominal diameter and RRP strands 108/127 used for the cable development (Filament diameter is ~ 46 micrometers) No cable fabrication made with PIT strands which are not available. First 3 runs dedicated to develop a cable with a width of 15.1 mm to minimize the Ic degradation. Last 4 runs dedicated to fabricate a cable with a width of 14.7 mm to improve the mechanical stability of the cable. Cable development work for the 11 T dipole cable

Nb 3 Sn Cable fabricated with a width of 15.1 mm and a mid-thickness of 1.28 mm, keystone angle not measured. The transposition pitch was reduced to 90 mm to have a cable without gaps between the strands, but the cable does not appear to be mechanically very stable. The stability of the cable was improved by decreasing the transposition pitch to 80 mm, but the cable is less flexible and highly nervous. Cable development for a cable width of 15.1 mm Ic degradation is close to zero (result obtained on 4 extracted strands) %, + 1 %, %, %

Nb 3 Sn Cable fabricated with a width of 14.7 mm, a mid- thickness of mm and a keystone angle of 0.71 o The transposition pitch was fixed to 100 mm. The mechanical stability of the Sc cable is quite good as seen by manual bending, but no winding test have been done with the Sc cable (short piece length of 10 m). The winding tests done with a Cu cable having a keystone angle of 0.88 o, but with a mid-thickness of 1.24 mm to have enough compaction on the thick edge, were successful either with a transposition pitch of 90 mm or 100 mm ( tension between 10 kg and 35 kg). Another Cu cable having the specified dimensions, a keystone angle of 0.8 o and a mid-thickness of mm was fabricated with a transposition pitch of 95 mm; cable having a very good quality (not used up to now for winding tests). Cable development for a cable width of 14.7 mm

Average Ic degradation is 2.6 % (result obtained on 6 extracted strands) - 6 %, - 2 %, %, %, %, % Ic degradation of the 14.7 mm wide cable

The next step for the cable development is to fabricate a cable with a keystone angle of 0.65 o and a mid-thickness of mm, in order to increase the mechanical stability of the cable and to decrease further the Ic degradation. Next step for cable development

Main Characteristics of the cable Width15.1 mm14.7 mm15.13 mm14.7 mm Mid-thickness1.269 mm mm1.269 mm1.254 mm Thin edge1.165 mm1.168 mm1.331 mm1.186 mm1.148 mm Thick edge1.373 mm1.370 mm1.520 mm1.352 mm1.350 mm Keystone angle0.79 o 0.75 o 0.65 o 0.79 o t/2d thin edge83.2 %83.4 %83.1 %84.7 %82.0 % t/2d thick edge98.1 %97.8 %95.4 %96.6 %96.5 % Compaction factor83.9 %86 %85.2 %86 %87.3 % Transposition pitch100 mm According to Dan Dietderich, LARP’s HQ cable is mechanically stable but only marginally. The LARP’s HQ cables have a thick edge deformation ratio (t/2d) = 0.95 – T dipole LARP’s HQ11 T dipole

Thank you for your attention !