High-heat-flux technologies for the European demo divertor targets: State-of-the-art and a review of the latest testing campaign

Divertor target is one of the most critical in-vessel components in a fusion power plant being in charge of particle and power exhaust. The targets are exposed to severe thermal loads produced by steady bombardment of impinging plasma flux. Since 2014, integrated R&D efforts have been continued...

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Bibliographic Details
Published in:Journal of nuclear materials 2021-02, Vol.544, p.152670, Article 152670
Main Authors: You, J.H., Visca, E., Barrett, T., Böswirth, B., Crescenzi, F., Domptail, F., Dose, G., Fursdon, M., Gallay, F., Greuner, H., Hunger, K., Lukenskas, A., Müller, A.v., Richou, M., Roccella, S., Vorpahl, C., Zhang, K.
Format: Article
Language:English
Subjects:
Armor
Bombardment
Comparative studies
Demo
Design
Divertor
Electric power generation
Fabrication
Fluctuations
Fusion reactor
Heat
Heat flux
Heat transfer
High heat flux
Infrared imagery
Infrared imaging
Infrared inspection
Inspection
Interlayers
Nuclear power plants
Photomicrographs
Power plants
R&D
Research & development
State-of-the-art reviews
Thermal analysis
Thermography
Tungsten
Tungsten monoblock
Ultrasonic testing
Vertical target
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Summary:Divertor target is one of the most critical in-vessel components in a fusion power plant being in charge of particle and power exhaust. The targets are exposed to severe thermal loads produced by steady bombardment of impinging plasma flux. Since 2014, integrated R&D efforts have been continued aiming at developing a design concept and high-heat-flux (HHF) technologies for divertor targets of the European DEMO reactor. Recently, the second round (2017–2019) of the R&D program has been concluded. As in the first R&D round, five water-cooled target design concepts were further developed and evaluated. Fabrication technologies were improved reaching a consolidated production quality. Extensive HHF tests were conducted using small-scale mock-ups for extended loading regimes (heat flux: 20–32MW/m²). Comparative studies were performed to investigate effects of copper interlayer thickness (0.1–1 mm) and different tungsten armor materials. In the present paper, the final results of the second round HHF testing campaign are reported. The HHF performance of each design variant is discussed based on in-situ diagnostic data (infrared thermography), ultrasonic inspection images and postmortem metallographic micrographs. All monoblock-type design concepts passed the specified qualification criterion (≥500 pulses at 20 MW/m², coolant: 130 °C) without any failure or armor cracking. Moreover, two of them (ITER-like and composite pipe) remained fully intact even under 25 MW/m² (100 pulses) and 32 MW/m² (5 pulses).
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2020.152670