Modélisation RF d'une cavité accélératrice supraconductrice

This note describes how to simply model the behavior of a superconductive accelerating cavity coupled with its environment RF and the beam it which is accelerated. The third equations governing the behavior of the system to the first order are described, and some remarkable properties of the system in stationary regime is in particular underlined.Cette note décrit commment modéliser simplement le comportement d'une cavité accélératrice supraconductrice couplée avec son environnement RF et le faisceau qu'elle accélère. Les équations régissant le comportement du système au premier ordre sont décrites, et quelques propriétés remarquables du système en régime stationnaire sont notamment soulignées

General Synthesis Report of the Different ADS Design Status. Establishment of a Catalogue of the R&D needs

This document is a General Synthesis Report of the Different ADS Design Status being designed within the EUROTRANS Integrated Project; an FP6 European commission partially funded programme. This project had the goal to demonstrate the possibility of nuclear waste transmutation/burning in Accelerator Driven Systems (ADS) at industrial scale.The focus is on a Pb-cooled ADS for the European Facility on Industrial scale Transmuter (ETD/EFIT) with a back-up solution based on an He cooled ADS.As an intermediate step towards this industrial-scale prototype, an eXperimental Transmuter based on ADS concept (ETD/XT-ADS) able to demonstrate both the feasibility of the ADS concept and to accumulate experience when using dedicated fuel sub-assemblies or dedicated pins within a MOX fuel core has been also studied.The two machines (XT-ADS and Pb cooled EFIT) have been designed in a consistent way bringing more credibility to the potential licensing of these plants and with sufficient details to allow definition of the critical issues as regards design, safety and associated technological and basic R&D needs. The different designs fit rather well with the technical objectives fixed at the beginning of the project in consistency with the European Roadmap on ADS development.For what concerns the accelerator, the superconducting LINAC has been clearly assessed as the most suitable concept for the three reactors in particular with respect to the stringent requirements on reliability. Associated R&D needs have been identified and will be focused on critical components (injector, cryomodule) long term testing.The design of the different ADS has been performed in view of what is reasonably achievable pending the completion of R&D programmes. The way the EUROTRANS Integrated Project has been organised with other domains than the DM1 Design being specifically devoted to R&D tasks in support to the overall ETD/EFIT and ETD/XT-ADS design tasks has been helpful. The other domains were centred on the assessment of reactivity measurement techniques (DM2 ECATS), on the development of U-free dedicated fuels (DM3 AFTRA), on materials behaviour and heavy liquid metal technology (DM4 DEMETRA) and on nuclear data assessment (DM5 NUDATRA). Pending questions associated to technology gaps have been identified through the different appropriate R&D work programmes and a Catalogue of the R&D needs has been established.Finally, the work within the EUROTRANS integrated project has provided an overall assessment of the feasibility at a reasonable cost for an ADS based transmutation so that a decision can be taken to launch a detailed design and construction of the intermediate step Experimental ADS now already launched within the 7th FP programme under the name of Common Design Team (CDT)

Modélisation RF d'une cavité accélératrice supraconductrice

This note describes how to simply model the behavior of a superconductive accelerating cavity coupled with its environment RF and the beam it which is accelerated. The third equations governing the behavior of the system to the first order are described, and some remarkable properties of the system in stationary regime is in particular underlined.Cette note décrit commment modéliser simplement le comportement d'une cavité accélératrice supraconductrice couplée avec son environnement RF et le faisceau qu'elle accélère. Les équations régissant le comportement du système au premier ordre sont décrites, et quelques propriétés remarquables du système en régime stationnaire sont notamment soulignées