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Benchmarking and Exploring Parameter Space of the 2-Phase Bubble Tracking Model for Liquid Mercury Target Simulation

by Lianshan Lin, Majdi I Radaideh, Hoang A Tran, Drew E Winder
Publication Type
Conference Paper
Book Title
NAPAC2022: Proceedings of the North American Particle Accelerator Conference
Publication Date
Page Numbers
711 to 714
Publisher Location
Geneva, Switzerland
Conference Name
North American Particle Accelerator Conference (NAPAC)
Conference Location
Albuquerque, New Mexico, United States of America
Conference Sponsor
APS Division of the Physics of Beams and IEEE
Conference Date
-

High intensity proton pulses strike the Spallation Neutron Source (SNS)’s mercury target to provide bright neutron beams. These strikes deposit extensive energy into the mercury and its steel vessel. Prediction of the resultant loading on the target is difficult when helium gas is intentionally injected into the mercury to reduce the loading and to mitigate the pitting damage on the vessel. A 2-phase material model that incorporates the Rayleigh-Plesset (R-P) model is expected to address this complex multi-physics dynamics problem by including the bubble dynamics in the liquid mercury. We present a study comparing the measured target strains in the SNS target station with the simulation results of the solid mechanics simulation framework. We investigate a wide range of various physical model parameters, including the number of bubble families, bubble size distribution, viscosity, surface tension, etc. to understand their impact on simulation accuracy. Our initial findings reveal that using 8-10 bubble families in the model renders a simulation strain envelope that covers the experimental ones. Further optimization studies are planned to predict the strain response more accurately.