Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
9845479 | Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment | 2005 | 5 Pages |
Abstract
IFE designs for thick liquid protection of heavy-ion inertial fusion reactors utilize banks of liquid jets to protect sensitive beam line components from neutrons and debris following target explosions. IFE designers must have knowledge of the surface quality of these jets in order to determine the distance between the jets and the ion beams that must propagate through the void spaces between them. Here, numerical simulations of such jet flows performed with the customized Flow3D solver are reported. These numerical simulations predicted no significant jet breakup in the region of interest, but did show surface and shape deformation that may end up determining the minimum standoff distance between jets and driver beams. The simulations also show small-droplet ejection that may adversely affect beam propagation characteristics. The intrusion distance of liquid into the beam lines was determined to be below 10% of the original jet thickness throughout the computational domain (up to 1Â m downstream from the nozzle). Recommendations on how to avoid or minimize unwanted hydrodynamic phenomena (surface rippling and droplet ejection) by upstream conditioning and nozzle design are developed for free surface jets in vacuum in the context of a qualitative understanding of the physical mechanisms at play.
Related Topics
Physical Sciences and Engineering
Physics and Astronomy
Instrumentation
Authors
A.I. Konkachbaev, N.B. Morley, M.A. Abdou,