INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST

S. X. Zhao; Q. Li; W. J. Wang; C. Li; D. D. Zhang; R. Wei; S. G. Qin; Y. L. Shi; L. J. Peng; N. J. Pan; Y. Xu; G. H. Liu; T. J. Wang; D. M. Yao; G. N. Luo

doi:10.13182/FST14-835

INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST

S. X. Zhao
, Q. Li
, W. J. Wang
, C. Li
, D. D. Zhang
, R. Wei
, S. G. Qin
, Y. L. Shi
, L. J. Peng
, N. J. Pan
, Y. Xu
, G. H. Liu
, T. J. Wang
, D. M. Yao
, G. N. Luo

CAS - Institute of Plasma Physics
Tsinghua University
Ltd.
Hefei Center for Physical Science and Technology
Chinese Academy of Sciences

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

A hot isostatic pressing (HIP) route has been developed by the Institute of Plasma Physics of the Chinese Academy of Sciences in collaboration with the Advanced Technology & Materials Co., Ltd. for bonding W/Cu tiles to Ni-electroplated CuCrZr heat sinks. During high-heat-flux testing, in the initial stage, Cu/ Ni interfacial debonding was observed. Careful analyses indi-cated that interfacial oxidation during encapsulation for HIP processing using tungsten inert gas (TIG) welding was the main cause of the limited fatigue lifetime. Copper oxides formed during the TIG encapsulation do not decompose during HIP at 600uC. As a result, weak bonding and even some microcracks were generated, and unfortunately these microcracks could not be detected by current industrial ultrasonic probes. An oxidation-free encapsulation technique, suitable for batch processing, has been developed to achieve a thermal fatigue lifetime of more than 1000 cycles at a heat load of 5 MW/m² for the components.

Original language	English
Pages (from-to)	784-791
Number of pages	8
Journal	Fusion Science and Technology
Volume	67
Issue number	4
DOIs	https://doi.org/10.13182/FST14-835
State	Published - 2015
Externally published	Yes

Keywords

W/Cu plasma-facing components
high-heat-flux test
interfacial oxidation

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10.13182/FST14-835

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Zhao, S. X., Li, Q., Wang, W. J., Li, C., Zhang, D. D., Wei, R., Qin, S. G., Shi, Y. L., Peng, L. J., Pan, N. J., Xu, Y., Liu, G. H., Wang, T. J., Yao, D. M., & Luo, G. N. (2015). INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST. Fusion Science and Technology, 67(4), 784-791. https://doi.org/10.13182/FST14-835

@article{87eeadff3f484d49b7945ae6ecdb3208,

title = "INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST",

abstract = "A hot isostatic pressing (HIP) route has been developed by the Institute of Plasma Physics of the Chinese Academy of Sciences in collaboration with the Advanced Technology \& Materials Co., Ltd. for bonding W/Cu tiles to Ni-electroplated CuCrZr heat sinks. During high-heat-flux testing, in the initial stage, Cu/ Ni interfacial debonding was observed. Careful analyses indi-cated that interfacial oxidation during encapsulation for HIP processing using tungsten inert gas (TIG) welding was the main cause of the limited fatigue lifetime. Copper oxides formed during the TIG encapsulation do not decompose during HIP at 600uC. As a result, weak bonding and even some microcracks were generated, and unfortunately these microcracks could not be detected by current industrial ultrasonic probes. An oxidation-free encapsulation technique, suitable for batch processing, has been developed to achieve a thermal fatigue lifetime of more than 1000 cycles at a heat load of 5 MW/m2 for the components.",

keywords = "W/Cu plasma-facing components, high-heat-flux test, interfacial oxidation",

author = "Zhao, \{S. X.\} and Q. Li and Wang, \{W. J.\} and C. Li and Zhang, \{D. D.\} and R. Wei and Qin, \{S. G.\} and Shi, \{Y. L.\} and Peng, \{L. J.\} and Pan, \{N. J.\} and Y. Xu and Liu, \{G. H.\} and Wang, \{T. J.\} and Yao, \{D. M.\} and Luo, \{G. N.\}",

year = "2015",

doi = "10.13182/FST14-835",

language = "英语",

volume = "67",

pages = "784--791",

journal = "Fusion Science and Technology",

issn = "1536-1055",

publisher = "Taylor and Francis Ltd.",

number = "4",

}

Zhao, SX, Li, Q, Wang, WJ, Li, C, Zhang, DD, Wei, R, Qin, SG, Shi, YL, Peng, LJ, Pan, NJ, Xu, Y, Liu, GH, Wang, TJ, Yao, DM & Luo, GN 2015, 'INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST', Fusion Science and Technology, vol. 67, no. 4, pp. 784-791. https://doi.org/10.13182/FST14-835

TY - JOUR

T1 - INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST

AU - Zhao, S. X.

AU - Li, Q.

AU - Wang, W. J.

AU - Li, C.

AU - Zhang, D. D.

AU - Wei, R.

AU - Qin, S. G.

AU - Shi, Y. L.

AU - Peng, L. J.

AU - Pan, N. J.

AU - Xu, Y.

AU - Liu, G. H.

AU - Wang, T. J.

AU - Yao, D. M.

AU - Luo, G. N.

PY - 2015

Y1 - 2015

N2 - A hot isostatic pressing (HIP) route has been developed by the Institute of Plasma Physics of the Chinese Academy of Sciences in collaboration with the Advanced Technology & Materials Co., Ltd. for bonding W/Cu tiles to Ni-electroplated CuCrZr heat sinks. During high-heat-flux testing, in the initial stage, Cu/ Ni interfacial debonding was observed. Careful analyses indi-cated that interfacial oxidation during encapsulation for HIP processing using tungsten inert gas (TIG) welding was the main cause of the limited fatigue lifetime. Copper oxides formed during the TIG encapsulation do not decompose during HIP at 600uC. As a result, weak bonding and even some microcracks were generated, and unfortunately these microcracks could not be detected by current industrial ultrasonic probes. An oxidation-free encapsulation technique, suitable for batch processing, has been developed to achieve a thermal fatigue lifetime of more than 1000 cycles at a heat load of 5 MW/m2 for the components.

AB - A hot isostatic pressing (HIP) route has been developed by the Institute of Plasma Physics of the Chinese Academy of Sciences in collaboration with the Advanced Technology & Materials Co., Ltd. for bonding W/Cu tiles to Ni-electroplated CuCrZr heat sinks. During high-heat-flux testing, in the initial stage, Cu/ Ni interfacial debonding was observed. Careful analyses indi-cated that interfacial oxidation during encapsulation for HIP processing using tungsten inert gas (TIG) welding was the main cause of the limited fatigue lifetime. Copper oxides formed during the TIG encapsulation do not decompose during HIP at 600uC. As a result, weak bonding and even some microcracks were generated, and unfortunately these microcracks could not be detected by current industrial ultrasonic probes. An oxidation-free encapsulation technique, suitable for batch processing, has been developed to achieve a thermal fatigue lifetime of more than 1000 cycles at a heat load of 5 MW/m2 for the components.

KW - W/Cu plasma-facing components

KW - high-heat-flux test

KW - interfacial oxidation

UR - https://www.scopus.com/pages/publications/85019500811

U2 - 10.13182/FST14-835

DO - 10.13182/FST14-835

M3 - 文章

AN - SCOPUS:85019500811

SN - 1536-1055

VL - 67

SP - 784

EP - 791

JO - Fusion Science and Technology

JF - Fusion Science and Technology

IS - 4

ER -

INFLUENCE OF INTERFACIAL OXIDATION ON THE HIGH-HEAT-FLUX PERFORMANCE OF HIP-MANUFACTURED FLAT-TYPE W/Cu PLASMA-FACING COMPONENTS FOR EAST

Abstract

Keywords

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