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Mechanical Properties of Roebel Coated Conductor Cable A.Kario 1, S. Otten 1,2, C. M. Bayer 1, M. Vojenciak 1,3, A. Kling 1, B. Ringsdorf 1, B. Runtsch.

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Presentation on theme: "Mechanical Properties of Roebel Coated Conductor Cable A.Kario 1, S. Otten 1,2, C. M. Bayer 1, M. Vojenciak 1,3, A. Kling 1, B. Ringsdorf 1, B. Runtsch."— Presentation transcript:

1 Mechanical Properties of Roebel Coated Conductor Cable A.Kario 1, S. Otten 1,2, C. M. Bayer 1, M. Vojenciak 1,3, A. Kling 1, B. Ringsdorf 1, B. Runtsch 1, W. Goldacker 1 1 Karlsruhe Institute of Technology, Institute for Technical Physics 2 University of Twente, Chair of Energy, Materials and Systems 3 Institute of Electrical Engineering, Slovak Academy of Science

2 Motivation Bending properties Tensile stress Transverse stress Need of impregnation current field forces G. Kirby et al., EuCARDII Meeting

3 Outline Bending properties Impregnation Transversal stress Tensile stress

4 Bending radii > 10 mm do not degrade the I c Cable geometry: 12 mm cable, 10 strands, TL: 126 mm Measurements on single strands show degradation in the bent section by < 1% Small degradation, < 6.5 % of total cable I c Cable degradation was not caused by bending r = 50 mm r = 10 mm To be published

5 Roebel cable is fragile to bending-torsion No reversibility in a case of 10 and 15 mm thickness 5% or 10% degradation at 20° winding angle Cable 10 or 15 mm diameter

6 Outline Bending properties Impregnation Transversal stress Tensile stress

7 Modelling of the stress in meander structure 4 mm Roebel cable Superpower tape: 100 µm thick, Yong modulus: 120 GPa Applied tensile load 1 kN Finite Element Method, Comsol Multiphysics C. Barth et al., Supercond. Sci. Technol. 25 (2012) 025007 (9pp)

8 Roebel strand geometry: outer corner and 10 mm inner radius High von Mises stress – concentrated in small areas, favour the growth of cracks Low von Mises stress – distributed over large area, cable can withstand high tensile load C. Barth et al., Supercond. Sci. Technol. 25 (2012) 025007 (9pp)

9 Outline Bending properties Impregnation Transversal stress Tensile stress

10 degradation of the individual strands I c by 30% at a transverse stress of 10 MPa. KIT cable: 10 strands, TL: 126 mm Effective stress: 167 MPa (24% surface) GCS cable: 15 strands, TL: 300 mm Effective stress: 111 MPa (36% surface) Different compressive stress values 10 – 40 MPa J. Fleiter et al., Supercond. Sci. Technol. 26 (2013) 065014 (5pp) D. Uglietti et al., Supercond. Sci. Technol. 26 (2013) 074002 (5pp)

11 Transversal stress test with additional copper strands Contact area of stainless steel: 4 mm x 85 mm stainless steel Roebel strands Copper strands

12 5% I c degradation by 68.8 MPa effective stress Average transverse stress (cable surface) Effective transverse stress To be published

13 Defects on the Roebel-bridge 60 K, 20 mT 61 K, 30 mT 2 mm 60 K, 25 mT 2 mm Magneto-optical Imaging I c measurements after deassembly of the Roebel cable To be published

14 Outline Bending properties Impregnation Transversal stress Tensile stress

15 Epoxy choice Commercially available resins with fillers Thermal expansion Thermal conductivity Chemical compatibility with REBCO Resin working temperature Resin viscosity Stress concentrations Low T c cable example Fred M. Asner, High Field Superconducting Magnets, CLARENDON PRESS OXFORD 1999

16 Thermal expansion similar to REBCO for more then 50% filled epoxy's Thermal expansion < 0.7 % preferred * C. Barth,PhD thesis (2013) N. Bagrets, ITEP, KIT * * * Thermal expansion (%) * To be published

17 Equal thermal conductivity at 4.2 K for silica and alumina filled epoxy's At 4.2 K, all epoxies have very low thermal conductivity Effect of fillers is small compared to 77-300 K * C. Barth, PhD thesis (2013) S. Drotziger, ITEP, KIT * * * λ (W/ m*K) 300 K 4.2 K * * * To be published

18 Impregnation of dummy Roebel cables Wet-winding Vacuum impregnation with fused silica Vacuum impregnation with fused silica and glass fibre To be published

19 Vacuum impregnation with Araldite and 50% fused silica Dummy between two stainless steel tapes Araldite CY5538/HY5571 with 50 wt% fused silica T = 80 °C, P = 0.3 kPa Thickness < 1 mm → high current density 100 µm stainless steel tape Epoxy filled central hole I c [A]n Before impregnation171.728.1 After impregnation170.226.8 After impregnation 2x170.928.5 Dummy with one SP REBCO strand I c measurement at 77 K No I c degradation To be published

20 Transverse pressure tests (U. Twente) W. Van de Camp, master thesis, University of Twente, 2012 Samples to be tested Reference cable Impregnated cable (CY5538/HY5571 + 50 wt% silica) Cryogenic press (UTwente) T = 4.2 K I max = 50 kA B max = 11 T (perpendicular) F max = 260 kN U-shaped samples

21 Bending Easy direction down to 10 mm radius: TL:126 mm, 10 strands cable Depends on: TL, no. of tapes, SC tape Tensile stress Optimised structure: outer corner, inner radius 10 mm (fixed) Transverse stress Impregnation support needed Impregnation Vacuum impregnation with Araldite 50% fused silica proposed Summary ? ? ? ? ? ? Bending properties Impregnation Transversal stress Tensile stress

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