Add to ORKGThe design of the prototype 120-keV, 65-A, 0.5-sec ion accelerator for TFTR-type beam systems is described. Details of the manufacture of the constituent parts are given along with descriptions of the major components of the accelerator. Included are the molybdenum grid structures, molybdenum shields, stainless steel hats and the epoxy insulator. Specific manufacturing problems are discussed along with the results of tests to determine the voltage holding capabilities of the assembly
ITER neutral beam injector (NBI) is required to produce 1 MeV 16.5 MW neutral beams for 3600 seconds...
The next generation of CTR experiments, such as the Tokamak Fusion Test Reactor (TFTR), will require...
Each Injector of the ITER Neutral Beam system will deliver a power up to 16.5MW and guarantee steady...
This final report summarizes the effort and presents the results of a Phase II fabrication effort to...
The neutral-beam injection requirements for heating and fueling the next generation of fusion reacto...
A conceptual design of a prototype beam line for the TFTR Neutral Beam System has been developed. Th...
The design and fabrication of a surface conversion negative ion source and an 80 keV pre-accelerator...
The development of high intensity neutral beam injectors at the Lawrence Berkeley Laboratory has pro...
The Lawrence Berkeley and Livermore Laboratories Neutral Beam Development Group's work proceeds alon...
At the Lawrence Livermore and Berkeley Laboratories two major neutral beam system designs were devel...
A comprehensive set of research and development activities has been carried out at Consorzio RFX reg...
From topical meeting on technology of controlled nuclear fusion; San Diego, California, USA (16 Apr ...
We have attempted to make detailed designs of several neutral beam systems which would be applicable...
Abstract. The paper reports the progress of R&D toward the ITER neutral beam (NB) system at Japa...
A discussion is provided of possible neutral beam requirements and constraints for a TFTR upgrade. T...
ITER neutral beam injector (NBI) is required to produce 1 MeV 16.5 MW neutral beams for 3600 seconds...
The next generation of CTR experiments, such as the Tokamak Fusion Test Reactor (TFTR), will require...
Each Injector of the ITER Neutral Beam system will deliver a power up to 16.5MW and guarantee steady...
This final report summarizes the effort and presents the results of a Phase II fabrication effort to...
The neutral-beam injection requirements for heating and fueling the next generation of fusion reacto...
A conceptual design of a prototype beam line for the TFTR Neutral Beam System has been developed. Th...
The design and fabrication of a surface conversion negative ion source and an 80 keV pre-accelerator...
The development of high intensity neutral beam injectors at the Lawrence Berkeley Laboratory has pro...
The Lawrence Berkeley and Livermore Laboratories Neutral Beam Development Group's work proceeds alon...
At the Lawrence Livermore and Berkeley Laboratories two major neutral beam system designs were devel...
A comprehensive set of research and development activities has been carried out at Consorzio RFX reg...
From topical meeting on technology of controlled nuclear fusion; San Diego, California, USA (16 Apr ...
We have attempted to make detailed designs of several neutral beam systems which would be applicable...
Abstract. The paper reports the progress of R&D toward the ITER neutral beam (NB) system at Japa...
A discussion is provided of possible neutral beam requirements and constraints for a TFTR upgrade. T...
ITER neutral beam injector (NBI) is required to produce 1 MeV 16.5 MW neutral beams for 3600 seconds...
The next generation of CTR experiments, such as the Tokamak Fusion Test Reactor (TFTR), will require...
Each Injector of the ITER Neutral Beam system will deliver a power up to 16.5MW and guarantee steady...