2011
DOI: 10.1016/j.fusengdes.2011.02.036
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Present status of the conceptual design of the EU test blanket systems

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Cited by 54 publications
(25 citation statements)
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“…Future helium power plants will also produce helium, both in the fusion reaction itself and through the action of the neutron multiplier, which we assume will be beryllium. In order to estimate helium inventories (loadings), loss rates and the helium production rate, we follow reference [80] and use design data from ITER [83], from the European DEMO power plant design project [84] and from the European test blanket project [85].…”
Section: Helium Requirements For Fusion Power Plantsmentioning
confidence: 99%
“…Future helium power plants will also produce helium, both in the fusion reaction itself and through the action of the neutron multiplier, which we assume will be beryllium. In order to estimate helium inventories (loadings), loss rates and the helium production rate, we follow reference [80] and use design data from ITER [83], from the European DEMO power plant design project [84] and from the European test blanket project [85].…”
Section: Helium Requirements For Fusion Power Plantsmentioning
confidence: 99%
“…Future helium power plants will also produce helium, both in the fusion reaction itself and through the action of the neutron multiplier. In order to estimate helium inventories (loadings) and the helium production rate, we use design data from ITER [19], from the European DEMO power plant [20] ( Table 2) and from the European test blanket project [21]. To achieve tritium self-sufficiency in a future fusion power plant, it will be necessary to employ a neutron multiplier, such as beryllium or lead, which produce further neutrons via (n, 2n) reactions in the blanket of the reactor.…”
Section: The Future Fusion Power Stationmentioning
confidence: 99%
“…To achieve tritium self-sufficiency in a future fusion power plant, it will be necessary to employ a neutron multiplier, such as beryllium or lead, which produce further neutrons via (n, 2n) reactions in the blanket of the reactor. In the DEMO reactor study [21] a power plant is described which uses helium coolant for two possible types of breeding blanket (HCLL and HCPB). The main DEMO parameters are given in Table 2.…”
Section: The Future Fusion Power Stationmentioning
confidence: 99%
“…This included two main milestones: ITER (International Tokamak Experimental Reactor) and DEMO (DEMOnstration Power Plant). The main objective of ITER is to demonstrate the technological feasibility of fusion energy by producing net thermal energy and testing the required materials [2]. DEMO will be a bridge between ITER and commercial fusion power plants, demonstrating the feasibility of the integration of all the required systems (reactor and balance of plant) to operate a fusion power plant, including issues of security, wastes management, maintenance, and so on.…”
Section: Introductionmentioning
confidence: 99%