TY - GEN
T1 - Numerical prediction of erosive collapse events in unsteady compressible cavitating flows
AU - Mihatsch, Michael S.
AU - Schmidt, Steffen J.
AU - Thalhamer, Matthias
AU - Adams, Nikolaus A.
N1 - Publisher Copyright:
© 2013 Springer Science+Business Media Dordrecht.
PY - 2013
Y1 - 2013
N2 - The objective of the present investigation is the numerical prediction of the potential of a flow to inflict surface damage by cavitation. For this purpose, physical criteria are derived that detect and quantify relevant flow phenomena. In particular, we present a numerical approach for tracing isolated collapses of vapor clouds during the numerical simulation of the flow. The suggested "collapse detector" provides the frequency of collapses, their positions, and resulting maximum pressures, as well as the maximum condensation rate of each event. This data, together with the maximum wall pressure, allow for an automatic indication of erosion-sensitive areas. The employed flow solver CATUM(CAvitation Technische UniversitätMünchen) is a density-based 3-D finite volume method equipped with a Low-Mach-number consistent flux function. All fluid components (liquid, vapor, saturated mixture) are modeled by closed form equations of state. To assess this novel approach we simulate an experimentally investigated nozzletarget flow. A comparison of numerically predicted collapse events with the experimentally observed areas of cavitation erosion substantiates the proposed methodology. The obtained data represents a time-history of collapse events together with their position and strength, and may be used to estimate erosion rates.
AB - The objective of the present investigation is the numerical prediction of the potential of a flow to inflict surface damage by cavitation. For this purpose, physical criteria are derived that detect and quantify relevant flow phenomena. In particular, we present a numerical approach for tracing isolated collapses of vapor clouds during the numerical simulation of the flow. The suggested "collapse detector" provides the frequency of collapses, their positions, and resulting maximum pressures, as well as the maximum condensation rate of each event. This data, together with the maximum wall pressure, allow for an automatic indication of erosion-sensitive areas. The employed flow solver CATUM(CAvitation Technische UniversitätMünchen) is a density-based 3-D finite volume method equipped with a Low-Mach-number consistent flux function. All fluid components (liquid, vapor, saturated mixture) are modeled by closed form equations of state. To assess this novel approach we simulate an experimentally investigated nozzletarget flow. A comparison of numerically predicted collapse events with the experimentally observed areas of cavitation erosion substantiates the proposed methodology. The obtained data represents a time-history of collapse events together with their position and strength, and may be used to estimate erosion rates.
KW - Cavitation
KW - Erosion
KW - Multiphase flow
KW - Numerical simulation
UR - http://www.scopus.com/inward/record.url?scp=84964237910&partnerID=8YFLogxK
U2 - 10.1007/978-94-007-6143-8_11
DO - 10.1007/978-94-007-6143-8_11
M3 - Conference contribution
AN - SCOPUS:84964237910
SN - 9789400761421
T3 - Computational Methods in Applied Sciences
SP - 187
EP - 198
BT - MARINE 2011, IV International Conference on Computational Methods in Marine Engineering
A2 - García-Espinosa, Julio
A2 - Oñate, Eugenio
A2 - Kvamsdal, Trond
A2 - Bergan, Pål
A2 - Eça, Luís
PB - Springer Netherland
T2 - 4th International Conference on Computational Methods in Marine Engineering, 2011
Y2 - 1 September 2011
ER -