1. logo area 11 T Wire: Procurement Strategy and QA/QC B. Bordini, A. Ballarino, M. Macchini Acknowledgments: thanks to E. Charifoullina for her contribution in the superconductor database development Review of the 11 T Dipoles at Collimator Section for the HL-LHC CERN – 7 th April 2016

2. logo area Outline  Wire Procurement  Quantities and Scheduling  Documentation from wire manufacturer  List of documents and measurements per shipment  Verification Measurements  Measurements carried out at CERN  Test load vs. laboratory capabilities  CERN Approval Procedure  Superconductor database  3 phases approval procedure  Tracing production  Conclusions 11 T Wire: Procurement Strategy and QA/QC – B. Bordini2

3. logo area Wire Procurement Number of Coils and Wire quantities  The total length is calculated with 10% margin  3 Unit lengths (86.6 km) for the LS2 prototype were produced with the 169 RRP  In total for LS2 we need 700 km of the RRP 108/127  The prototype for LS3 will use the PIT conductor  In total for LS3 about 1500 km of wire (RRP and PIT) 11 T Wire: Procurement Strategy and QA/QC – B. Bordini3 LS2 LS3

4. logo area Wire Procurement Schedule 11 T Wire: Procurement Strategy and QA/QC – B. Bordini4 F.C.  Financial Committee S.  Signed (contract) S.R.  Strand Received (first shipment) 500 km RRP 108/127 200 km RRP 108/127 1500 km 5 RRP Cables for Prototype 15 RRP Cables for LS2 Series 5 RRP Cables for LS2 Series 7 PIT Cables for Prototype 38 Cables for LS3 Series 3 Cables from previous order

5. logo area Documentations List of Documents per Shipment  Certificate of Conformance for Delivery  List of spools (CERN and OST ID), Shipped Length, Order Length, Order Weight  Pedigree Report  Sub-Elements and ID of the raw material used in each billet  Raw Material Certificates  Production History  Pieces after intermediate draw (1.6 mm), pieces after final inspection, gross yield (km and %), phase when breakages or cuts occurred  QA Datasheets – Results of the measurements on the wire 11 T Wire: Procurement Strategy and QA/QC – B. Bordini5

6. logo area Documentations QA Datasheets – Meas. per Piece Length  Continuous measurements of the diameter, ovality and eddy current  At least * : 1 Copper to not-Copper, 1 Twist Pitch length and direction, I c and 1 RRR - (tail of the piece length) *Additional measurements: 1 Cu to not-Cu, 1 Twist Pitch, 1 I c and 1 RRR on the point of the piece length in the case of  the first delivered piece length of a billet  a piece length following a not delivered piece length 11 T Wire: Procurement Strategy and QA/QC – B. Bordini6 Each extremity of the delivered piece lengths are characterized ** XXXX X ** The X indicate the locations of the measured samples

7. logo area Documentations QA Datasheets – Meas. per Billet  2 micrographs (point and tail) with measurements of the minimum and maximum dimensions of the sub-elements  1 micrograph (tail) of the rolled wire  6 sharp bend tests (3 billet point, 3 billet tail)  6 spring back test (3 billet point, 3 billet tail)  1 I c of 15 % rolled sample (billet tail)  1 RRR of 15 % rolled sample (billet tail) 11 T Wire: Procurement Strategy and QA/QC – B. Bordini7

8. logo area Documentations CERN Measurements  1 micrographs x billet (tail)  6 sharp bend tests x billet (3 point, 3 tail)  6 spring back test x billet (3 point, 3 tail)  1 I c of 15 % rolled sample x billet (tail)  1 RRR of 15 % rolled sample x billet (tail)  1 magnetization sample x billet  1 diameter, 1 Copper to not-Copper, 1 Twist Pitch length and direction, I c and 1 RRR x piece length - (tail) 11 T Wire: Procurement Strategy and QA/QC – B. Bordini8

9. logo area Verification Measurements I c measurements per Quarter  200 km (about 50 % for 11 T and 50 % for MQXF) of wire and samples from 6 cables to be qualified per quarter  Verification samples (from the 200 km of wire):  Scenario I:  1 sample per piece length (+ 1 rolled per billet)  4.5 piece lengths per billet  132 measurements  yield equal to 80 %  Scenario II:  3 samples per billet (+ 1 rolled per billet)  96 measurements  yield equal to 80 %  Additional samples: 36 cable samples, 36 coil witness samples  In total 204 measurements in case of scenario I and 168 measurements in case of scenario II 11 T Wire: Procurement Strategy and QA/QC – B. Bordini9

10. logo area Verification Measurements Laboratory Capability per Quarter  Max I c test capability of the laboratory  6 samples per day (3 test stations)  Assuming 58 days per quarter (once having taken into account holidays and maintenance) 348 measurements  The laboratory would be occupied  58.6% of its capability in case of scenario I (204 I c measurements)  48.3% in case of scenario II (168 I c measurements) 11 T Wire: Procurement Strategy and QA/QC – B. Bordini10

11. logo area Approval Procedure Database: 3 phases approval procedure  The data from the manufacturer (QA datasheets) are in Excel format and are uploaded automatically in the CERN superconductor database  The results of the CERN verification measurements are also stored in the superconductor database  The approval procedure is managed via the superconductor database and it is divided in three phases: 1.Analysis of the manufacturer data: completeness and conformity. The manufacturer will obtain the green light for shipping the material only when this phase will be by approved 2.Analysis of the CERN Verification measurements: conformity with respect to the technical specification 3.Comparison between manufacturer and CERN data: the difference shall be limited 11 T Wire: Procurement Strategy and QA/QC – B. Bordini11

12. logo area Approval Procedure Tracing Production 11 T Wire: Procurement Strategy and QA/QC – B. Bordini12 Quantity [km]246.96 n° billets23 Average I c, RMS [A]461.4, 18 Average RRR, RMS293.6, 40.8

13. logo area Approval Procedure Tracing Production 11 T Wire: Procurement Strategy and QA/QC – B. Bordini13

14. logo area Conclusions  The procurement strategy and the wire measurement capability of the laboratory satisfy the needs of the project  To guarantee the quality of the received wire, CERN requires for each billet  A comprehensive documentation that describes the production process and the used raw material  A detailed measurement campaign from the manufacturer  Extensive verification measurements that cross-check the manufacturer data  All the data are stored (electronically) in the superconductor database and an extract of these results is sent to the WP11 QA team  The material approval procedure is managed via the superconductor database  Matlab routines, which extract the data from the superconductor database, trace the evolution of the wire production 11 T Wire: Procurement Strategy and QA/QC – B. Bordini14

15. logo area Thank You For Your Attention ! 11 T Conductor Performance – B. Bordini15  The procurement strategy and the wire measurement capability of the laboratory satisfy the needs of the project  To guarantee the quality of the received wire, CERN requires for each billet  A comprehensive documentation that describes the production process and the used raw material  A detailed measurement campaign from the manufacturer  Extensive verification measurements that cross-check the manufacturer data  All the data are stored (electronically) in the superconductor database and an extract of these results is sent to the WP11 QA team  The material approval procedure is managed via the superconductor database  Matlab routines, which extract the data from the superconductor database, trace the evolution of the wire production