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Outline: Strand R&D and strand procurement and inventory. Main parameters of the cable without a core. Results obtained during the cable development without.

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Presentation on theme: "Outline: Strand R&D and strand procurement and inventory. Main parameters of the cable without a core. Results obtained during the cable development without."— Presentation transcript:

1 Outline: Strand R&D and strand procurement and inventory. Main parameters of the cable without a core. Results obtained during the cable development without a core. Results of the fabrication of dummy cables with a core. Future cable development work. CERN strand and cable R&D, strand procurement, and cable fabrication for the 11 T dipole Luc Oberli 1

2 PIT strands have not been used for cable development but will be used soon. PIT 114 with Ta doping under fabrication by Bruker and should be delivered in October 2012 (sub-element diameter = 45  m). RRP strands have been used for the cable development and for the fabrication of the first cables for the demonstrator. 2 type of strands were used : RRP 54/61 and RRP 108/127 RRP 108/127 with Ta doping is characterized by sub-element diameter of 45  m and by a Jc(12T, 4.2K) = 2800 A/mm 2 for the heat treatment 48h/210C + 48h/400C + 50h/665C. RRP 132/169 with Ti doping under fabrication by OST (d = 42  m) RRP 180/217 with Ti doping under development by OST (d = 36  m) Strand R&D and strand procurement 2

3 Inventory of the strand for the demonstrator and the prototype QuantityStrand typeAvailabilityTarget use 23 kmRRP 108/127In stock2 UL for the aperture 1 of the first 2 in 1 demonstrator Q1-13 10 kmRRP 108/127To be delivered by Fermi Lab 1 UL for a spare coil for the first 2 in 1 demonstrator Q1-13 45 km~ 30 km of RRP 132/169 November 20123 UL for the aperture 1 of the second 2 in 1 demonstrator ~ 15 km of RRP 180/217 February 20131 UL for a spare coil 45 km20 km of PIT114October 20122 UL for the aperture 2 of the first 2 in 1 demonstrator Q2-13 20 km of PIT114November 20122 UL for the aperture 2 of the second 2 in 1 demonstrator 150 km~ 50 km of RRP 132/169 Expected November 20132 UL for the CERN 5.5 m prototype ~ 50 km of RRP 132/169 Expected February 20142 UL for the CERN 5.5 m prototype ~ 50 km of RRP 132/169 Expected May 20142 UL for the CERN 5.5 m prototype 150 km~ 50 km of PIT 114Expected September 20132 UL for the CERN 5.5 m prototype ~ 50 km of PIT 114Expected December 20132 UL for the CERN 5.5 m prototype ~ 50 km of PIT 114Expected March 20142 UL for the CERN 5.5 m prototype 3

4 Main parameters of the cable without a core Width14.7 mm Number of strands40 Mid-thickness1.269 mm1.250 mm Thin edge1.168 mm1.149 mm Thick edge1.370 mm1.351 mm Keystone angle0.79 o t/2d thin edge83.4 %82.5 % t/2d thick edge97.8 %96.5 % Compaction factor86 %87.3 % Transposition pitch100 mm 4

5 Overview of the cable development work at CERN 3 types of cable without a core were fabricated to optimize the cable parameters for the 11 T dipole. 1.A 14.7 mmm wide cable with a mid-thickness of 1.269 mm and a keystone angle of 0.71 o. (run 57) short piece of ~ 15 m 2.A 14.7 mm wide cable with a mid-thickness of 1.254 mm and a keystone angle of 0.75 o. (run 62) unit length of 230 m 3.A 14.7 mm wide cable with a mid-thickness of 1.26 mm and a keystone angle of 0.58 o. (run 66) short piece of ~ 15 m 3 types of cable with a 12 mm wide 316L core (25  m thick) were fabricated for the winding of the first practice coils at CERN for the demonstrator 1.2 unit length of 230 m with hard Cu strand (keystone angle 0.79 o ) 2.130 m with hard Cu strand, 1/2 with a core of 11 mm and 1/2 with a core of 12 mm 3.2 unit length of 235 m with bronze strand produced for ITER by WST (keystone angle 0.74 o ) (run 73) 4.1 unit length of 230 m with RRP 54/61 (keystone angle 0.77 o ) (run 75) 5

6 Average Ic degradation is - 2.6 % (result obtained on 6 extracted strands) - 6 %, - 2 %, - 0.8 %, - 5.6 %, - 1.3 %, + 0.1 % First trial fabrication of the 14.7 mm wide cable (Run 57B) Cable fabricated without a core Cable mid-thickness 1.269 mm Keystone angle 0.71 o 6

7 Fabrication of the 1st long cable (Run 62B) for the demonstrator built at Fermilab Average Ic degradation is - 2.1 % (result obtained on 4 extracted strands) for the HT 48h/210C, 48h/400C, 50h/665C - 6.5 %, - 2.1 %, + 0.5 %, - 0.4 % Cable fabricated without a core Cable mid-thickness 1.254 mm Keystone angle 0.75 o 7

8 V-I tests : premature quenches are starting already at 8 Tesla for all the extracted strands while for virgin strands the premature quenches are starting at 6 Tesla. V-H tests were performed at low field on 4 extracted strands from the cable 62B. (heat treatment 48h/210C + 48h/400C + 50h/665C) Sample 51O00062BF11E : 700 A > Is > 650 A at 4.3 K 750 A > Is > 700 A at 2.04 K Sample 51O00062BF12E : 700 A > Is > 600 A at 4.3 K Sample 51O00062BF13E : 750 A > Is > 700 A at 4.3 K Sample 51O00062BF14E : 750 A > Is at 4.3 K Measurement of the stability current of few extracted strands from the cable 62B The stability current is lower than 700 A and greater than 600 A at 4.3 K and greater than 700 A at 2 K. 1. 2. 8

9 Ic degradation of a cable with a keystone angle of 0.58 O fabricated to improve the mechanical stability of the cable mid-thickness = 1.26 mm (Run 66) Average Ic degradation is + 0.9 % (result obtained on 6 extracted strands) for the HT 48h/210C, 48h/400C, 50h/665C + 1.2 %, + 1.5 %, + 0.1 %, + 1.6 %, + 0.1 %, + 1.0 % Ic degradation of the rectangular cable for the RMC, mid-thickness = 1.255 mm (Run 63) Average Ic degradation is + 1.1 % (result obtained on 4 extracted strands) for the HT 48h/210C, 48h/400C, 50h/665C + 1.0 %, + 5 %, - 0.6 %, - 1.0 Ic degradation of 2 cables with a smaller compaction for the thin edge 9

10 Dummy Cu cable with a 12 mm and 11 mm wide core 12 mm 11 mm 10

11 Dummy cable with a 12 mm wide core Core cable fabricated with bronze strands Core cable fabricated with RRP 54/61 strands 11

12 The value of the Ic degradation for the cable without a core is low even with a mid-thickness of 1.25 mm. No problem with magnetic instabilities at low field with the RRP 108/127 strand, Is greater than 700 A at 2 K. The fabrication of the core cable is well under control. Cable fabrication with PIT strand shall be performed to confirm the choice of the cable mid-thickness. Summary 12

13 Width14.7 mm15.13 mm14.7 mm Mid-thickness1.269 mm1.430 mm1.269 mm1.250 mm Thin edge1.168 mm1.331 mm1.186 mm1.149 mm1.167 mm Thick edge1.370 mm1.520 mm1.352 mm1.351 mm1.333 mm Keystone angle0.79 o 0.75 o 0.65 o 0.79 o 0.65 o t/2d thin edge83.4 %83.1 %84.7 %82.5 %83.3 % t/2d thick edge97.8 %95.4 %96.6 %96.5 %95.2 % Compaction factor 86 %85.2 %86 %87.3 % Transposition pitch 100 mm 11 T dipoleLARP’s HQ11 T dipole 13

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