Assessment of DEMO WCLL breeding blanket primary heat transfer system isolation valve absorbed doses due to activated water

•Assessment of the spatial distribution of the absorbed dose in the DEMO Upper Pipe Chase due to nitrogen isotopes in BB PHTSs.•Investigation of the absorbed dose in a typical isolation valve of the BB PHTS considering a period of 7 full power years.•The calculation of the absorbed dose has been car...

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Veröffentlicht in:Fusion engineering and design 2020-11, Vol.160, p.111999, Article 111999
Hauptverfasser: Chiovaro, P., Ciattaglia, S., Cismondi, F., Del Nevo, A., Di Maio, P.A., Federici, G., Moscato, I., Spagnuolo, G.A., Vallone, E.
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Sprache:eng
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Zusammenfassung:•Assessment of the spatial distribution of the absorbed dose in the DEMO Upper Pipe Chase due to nitrogen isotopes in BB PHTSs.•Investigation of the absorbed dose in a typical isolation valve of the BB PHTS considering a period of 7 full power years.•The calculation of the absorbed dose has been carried out adopting MCNP5 Monte Carlo code. Within the framework of the activities foreseen by the EUROfusion action on the cooling water activation assessment for a DEMO reactor equipped with a Water Cooled Lithium Lead Breeding Blanket (WCLL BB), the University of Palermo is involved in the investigation of the absorbed dose induced by the decay of nitrogen radioisotopes produced by water activation, in the main components (e.g. isolation valves) of both First Wall (FW) and Breeder Zone (BZ) cooling circuits. The aim of this work is to assess the spatial distribution of the absorbed dose in the DEMO Upper Pipe Chase (UPC), focusing the attention on the space neighbouring a typical isolation valve of the Primary Heat Transfer System (PHTS), taking into account a period of 7 full power years. To this end, a computational approach has been followed adopting MCNP5 Monte Carlo code. In particular, a totally heterogeneous neutronic model of a portion of the UPC has been set up, including the valve and the main FW and BZ PHTS piping, and the spatial distribution of nitrogen isotopes concentrations, previously assessed, have been used to model the photonic and neutronic sources. The results obtained, herewith presented and critically discussed, provided some information on the nuclear issues of the WCLL BB PHTS, to be considered as hints for the blanket design optimization.
ISSN:0920-3796
1873-7196
DOI:10.1016/j.fusengdes.2020.111999