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Comparative study of different Sn wetted W CPSs exposed to NBI fluxes in the OLMAT facility

E. Oyarzábal, F.L. Tabarés, M. Liniers, D. Alegre, D. Tafalla, K. J. McCarthy, A. de Castro, T.W. Morgan, J.G.A. Scholte, М. Иафрати, E. de la Cal, I. Voldimer, E. Ascasíbar, A. Soleto

2023Fusion Engineering and Design17 citationsDOIOpen Access PDF

Abstract

Four different tin-wetted, tungsten CPS (Capillary Porous System) targets where exposed to NBI pulses in the OLMAT High Heat flux (HHF) facility. They include two flexible ones placed on a TZM support (W meshes and W felt) and two compact ones (sintered W disk and 3D printed W). A comparative study was performed using a fast-frame imaging camera and an infrared pyrometer. Surface temperature increase and homogeneity, particle ejection, CPS damage and overall behaviour were studied for each case. Sn drop/accumulation at the lower part of the targets was observed for all cases when they are heated up to around 400 °C except for the 3D printed W target that has its own Sn deposit. The 3D printed W target presented the best results in all aspects, withstanding heat pulses up to 58 MW/m2 in 100 ms without any damage or particle ejection. On the other hand, the W mesh targets displayed damage at 20 MW/m2 due to a bad thermal contact with the deposit, while the sintered W disk developed a crack during a series of 15 MW/m2 NBI pulses. As might be expected, a reduced increase of temperature during pulses is observed for the two compact W targets. The results and their relevance for the design of a Sn wetted W CPS for application as a DEMO-divertor material are discussed in the present work.

Topics & Concepts

Materials scienceTungstenPyrometerHomogeneity (statistics)Polygon meshHeat fluxComposite materialTinPorosityDrop (telecommunication)Nuclear engineeringTemperature measurementHeat transferMetallurgyMechanicsMechanical engineeringComputer sciencePhysicsEngineeringMachine learningQuantum mechanicsComputer graphics (images)Fusion materials and technologiesNuclear Materials and PropertiesMagnetic confinement fusion research