Metallographic autopsies of full-scale ITER prototype cable-in-conduit conductors after full testing in SULTAN: 1. The mechanical role of copper strands in a CICC

Sanabria, Charlie; Lee, Peter J.; Starch, William; Blum, Timothy; Devred, A.; Jewell, M. C.; Pong, Ian; Martovetsky, N.; Larbalestier, D. C.

doi:10.1088/0953-2048/28/8/085005

Cited by 23 publications

(39 citation statements)

References 32 publications

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“…At very high pressure values, due to their brittleness, fracture of Nb 3 Sn filaments may occur if the mechanical loading exceeds the Nb 3 Sn crack initiation It is worth mentioning here the extensive metallographic analysis 59 , 60 carried out for the ITER cable-in-conduit conductors, in order to explore the role of the Lorentz loads in producing fractures in the brittle Nb 3 Sn filaments. Detailed filament crack count and fracture analysis classification have unambiguously evidenced the presence of ratcheted crack opening under electromagnetic cycling.…”

Section: Discussionmentioning

confidence: 99%

On the mechanisms governing the critical current reduction in Nb3Sn Rutherford cables under transverse stress

Marzi

Bordini

Baffari

2021

Sci Rep

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Within the framework of the HiLumi-LHC project, CERN is currently manufacturing 11 T dipole and quadrupole accelerator magnets using state-of-the-art Nb3Sn Rutherford cables. Even higher magnetic fields are considered by the Hadron Future Circular Collider (FCC-hh) design study, which plans to develop 16 T Nb3Sn bending dipoles. In such high-field magnets, the design pre-stress can reach considerable values (150–200 MPa) and, since Nb3Sn is a brittle compound, this can constitute a technological difficult challenge. Due to the significant impact that a transverse load can have on the performances of a Nb3Sn magnet, CERN has launched a campaign of critical current measurements of reacted and impregnated Nb3Sn cables subjected to transverse pressure up to about 210 MPa. In this paper, results obtained on 18-strand 10-mm-wide cable sample based on a 1-mm-diameter powder-in-tube (PIT) wire are presented. The tests were carried out on a 2-m-long sample by using the FReSCa test station, at T = 4.3 K and background magnetic fields up to 9.6 T. For applied pressures below ≈ 130 MPa, only reversible reductions of the critical current, Ic, are observed. At higher pressures, a permanent Ic reduction occurs; such irreversible behaviour is due to the residual stresses generated by the plastic deformations of the copper stabilizer. This type of current reduction, whether reversible or not, is fully governed by the strain-induced variations of the upper critical field, Bc2. At higher pressures, estimated between 180 and 210 MPa, it is indeed plausible to believe that cracking of filaments occurs, with detrimental consequences for the Nb3Sn cable’s electrical performances. The complete set of critical current data here presented, collected at different pressures and as a function of the applied magnetic field, allows for the first time to investigate the evolution of superconducting parameters such as the upper critical field Bc2 in the irreversibility region, where both the effects of Cu matrix plasticization and/or cracking of filaments may occur. The experimental approach and data interpretation have a general value and can be applied to any typology of Rutherford cable.

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Section: Discussionmentioning

confidence: 99%

On the mechanisms governing the critical current reduction in Nb3Sn Rutherford cables under transverse stress

Marzi

Bordini

Baffari

2021

Sci Rep

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“…Composite theory predicts iso-strain in the composite constituents under axial loading [16]. This has been confirmed experimentally for the Nb 3 Sn filaments and Cu matrix in different Nb 3 Sn wires by high energy synchrotron x-ray diffraction [16], and in ten-stack samples by neutron diffraction [8]. At 210 MPa (sample 28), the macroscopic axial ten-stack stresses in the Nb 3 Sn and Cu are about 450 MPa and 100 MPa, respectively [17].…”

Section: Description Of 11 T Dipole Cable Ten-stack Samplesmentioning

confidence: 72%

“…A post-mortem (destructive post magnet testing) metallographic analysis technique has been developed in order to provide more in-depth insight, at the conductor level, into the degradation and complexity in stress states. This approach was previously demonstrated in Nb 3 Sn cable-in-conduit magnet sections tested for the ITER project [7][8][9].…”

Section: Introductionmentioning

confidence: 96%

Metallographic analysis of 11 T dipole coils for High Luminosity-Large Hadron Collider (HL-LHC)

Balachandran¹,

Cooper

Oss

et al. 2021

Supercond. Sci. Technol.

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For next-generation accelerator magnets for fields beyond those achievable using Nb-Ti, Nb 3 Sn is the most viable superconductor. The high luminosity upgrade for the Large Hadron Collider (HL-LHC) marks an important milestone as it will be the first project where Nb 3 Sn magnets will be installed in an accelerator. Nb 3 Sn is a brittle intermetallic, so magnet coils are typically wound from composite strands containing ductile precursors before heat treating the wire components to form Nb 3 Sn. However, some mechanical assembly is still required after the coils have been heat-treated. In this paper, we present direct evidence of cracking of the brittle Nb 3 Sn filaments in a prototype dipole that resulted in degraded magnet performance. The cracking of the Nb 3 Sn, in this case, can be attributed to an issue with the collaring process that is required in the assembly of dipole accelerator magnets. Metallographic procedures were developed to visualize cracks present in the cables, along with quantitative image analysis for location-based crack analysis. We show that the stresses experienced in the damaged coil are above the critical damage stress of Nb 3 Sn conductor, as evidenced by a measured Cu stabilizer hardness of 85 HV 0.1 , which is higher than the Cu stabilizer hardness in a reference Nb 3 Sn cable ten-stack that was subjected to a 210 MPa transverse compression. We also show that once the collaring procedure issue was rectified in a subsequent dipole, the Nb 3 Sn filaments were found to be undamaged, and the Cu stabilizer hardness values were reduced to the expected levels. This paper provides a post-mortem verification pathway to analyze the damage, provides strand level mechanical properties, which could be beneficial for improving model prediction capabilities. This method could be applied beyond Nb 3 Sn magnets to composite designs involving high work hardening materials.

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“…这与Mitchell [39] 以及Nijhuis [77] 的预测结果截然相反. [72] 的实验结果冲突. Nabara等人 [85] 对两种具有相同节距的CSJA 导体进行电磁循环加载测试发现两个CSJA导体分流温度均随着电磁循环次数的增加而下降, 而且下降趋势大致相同.…”

Section: 发现标准的Csio1导体与长节距csio2-ltp导体分unclassified

“…Calzolaio和Bruzzone [107] 的磁化测试等效应变实验同样显示, 短节距导体内部等效压缩应变随循环次数的增加而减小, Harjo等人 [86] 用中子散射的方法发现了相同的规律. 近年来Takahashi等人 [113] , Sanabria等人 [72,115,116] , Qin等人 [117] 和Tomone等人 [118] 研究发现横向电磁力作用下的股线弯曲、挤压变形、芯丝断裂等并非是导致T cs 退化的主要原因. 并且认为电缆与导体之间可能存在slip-stick(黏滑)行为是造成T cs 变化的主要机制 [116] .…”

Section: 发现标准的Csio1导体与长节距csio2-ltp导体分unclassified

Research progress on the mechanical behavior of the cable in conduit conductor for the international thermonuclear experimental reactor project

2017

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Metallographic autopsies of full-scale ITER prototype cable-in-conduit conductors after full testing in SULTAN: 1. The mechanical role of copper strands in a CICC

Cited by 23 publications

References 32 publications

On the mechanisms governing the critical current reduction in Nb3Sn Rutherford cables under transverse stress

On the mechanisms governing the critical current reduction in Nb3Sn Rutherford cables under transverse stress

Metallographic analysis of 11 T dipole coils for High Luminosity-Large Hadron Collider (HL-LHC)

Research progress on the mechanical behavior of the cable in conduit conductor for the international thermonuclear experimental reactor project

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