Solutions for the steady-state power exhaust problem in future fusion reactors (e.g. DEMO) are not automatically provided by present experiments or even ITER, because the expected heat fluxes, as well as the level of neutron irradiation, will be much higher. Dedicated work packages are being devoted to this problem within EUROfusion and even a dedicated facility (the Divertor Tokamak Test – DTT) is being proposed by Italy. Among the possible solutions, a liquid metal (LM) divertor has been proposed more than 20 years ago. The particularly attractive feature of this solution is obviously the absence of damage to the wall, even in case of large heat fluxes, thanks to the high latent heat of evaporation, to the liquid nature of the wall –that can be refilled- and to the lithium vapor shield effect. The present work aims at developing a first model of the LM loop, which will be the core of the tools to be developed and eventually applied to the conceptual design of a LM divertor for the DTT facility. The model will describe the transport of the LM in the evaporation chamber, including its interaction with the plasma.

Thermodynamics of the Lithium Loop in a Liquid Metal Divertor for Future Fusion Reactors

AQUARO, DONATO;LO FRANO, ROSA;
2016-01-01

Abstract

Solutions for the steady-state power exhaust problem in future fusion reactors (e.g. DEMO) are not automatically provided by present experiments or even ITER, because the expected heat fluxes, as well as the level of neutron irradiation, will be much higher. Dedicated work packages are being devoted to this problem within EUROfusion and even a dedicated facility (the Divertor Tokamak Test – DTT) is being proposed by Italy. Among the possible solutions, a liquid metal (LM) divertor has been proposed more than 20 years ago. The particularly attractive feature of this solution is obviously the absence of damage to the wall, even in case of large heat fluxes, thanks to the high latent heat of evaporation, to the liquid nature of the wall –that can be refilled- and to the lithium vapor shield effect. The present work aims at developing a first model of the LM loop, which will be the core of the tools to be developed and eventually applied to the conceptual design of a LM divertor for the DTT facility. The model will describe the transport of the LM in the evaporation chamber, including its interaction with the plasma.
2016
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11568/833440
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