TY - GEN
T1 - Numerical simulation of cavitating ship propeller flow and assessment of erosion aggressiveness
AU - Budich, Bernd
AU - Schmidt, Steffen J.
AU - Adams, Nikolaus A.
PY - 2015
Y1 - 2015
N2 - Our contribution focuses on the evaluation of cavitation aggressiveness on the cavitating model propeller VP1304 by numerical simulation. To this respect, we employ a density-based, finite volume method, based on a barotropic, homogeneous mixture model. Fully accounting for two-phase compressibility, collapse-induced instantaneous peak pressures and associated wave dynamics are captured by the chosen approach. The maximum instantaneous pressures registered on material surfaces allow for a qualitative identification of erosion-sensitive areas. Furthermore, a collapse detection algorithm is applied for an automated recording of isolated cavity collapse events. Impact load spectra showing rate and intensity distributions of recorded collapses is utilized for a quantitative evaluation of cavitation aggressiveness. While the cavitating tip vortex is stable and does not lead to collapse events in the vicinity of the propeller, material erosion can be expected in the suction side root region due to a highly unsteady root cavitation.
AB - Our contribution focuses on the evaluation of cavitation aggressiveness on the cavitating model propeller VP1304 by numerical simulation. To this respect, we employ a density-based, finite volume method, based on a barotropic, homogeneous mixture model. Fully accounting for two-phase compressibility, collapse-induced instantaneous peak pressures and associated wave dynamics are captured by the chosen approach. The maximum instantaneous pressures registered on material surfaces allow for a qualitative identification of erosion-sensitive areas. Furthermore, a collapse detection algorithm is applied for an automated recording of isolated cavity collapse events. Impact load spectra showing rate and intensity distributions of recorded collapses is utilized for a quantitative evaluation of cavitation aggressiveness. While the cavitating tip vortex is stable and does not lead to collapse events in the vicinity of the propeller, material erosion can be expected in the suction side root region due to a highly unsteady root cavitation.
KW - Cavitation erosion
KW - Numerical simulation
KW - Propeller cavitation
UR - http://www.scopus.com/inward/record.url?scp=84938870368&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84938870368
T3 - MARINE 2015 - Computational Methods in Marine Engineering VI
SP - 709
EP - 721
BT - MARINE 2015 - Computational Methods in Marine Engineering VI
A2 - Muscari, Roberto
A2 - Broglia, Riccardo
A2 - Salvatore, Francesco
PB - International Center for Numerical Methods in Engineering
T2 - 6th International Conference on Computational Methods in Marine Engineering, MARINE 2015
Y2 - 15 June 2015 through 17 June 2015
ER -