Numerical investigation of tip-vortex cavitation noise of submarine propellers using hybrid computational hydro-acoustic approach

“…Depending on how various turbulence length scales are modelled or resolved, applied CFD methods can be classified as (Li et al, 2018): RANS or Unsteady RANS if the flow is treated as unsteady (Sezen et al, 2021c,b,a;Lee et al, 2021;Ge et al, 2020;Yao et al, 2021;Melissaris et al, 2020;Wu et al, 2018;Peters et al, 2018;Huang et al, 2019b;Lidtke et al, 2019); Detached Eddy Simulations (DES) (Ku et al, 2021;Usta and Korkut, 2019;Long et al, 2021;Yilmaz et al, 2020;Sezen et al, 2021a;Sakamoto and Kamiirisa, 2018); and Large Eddy Simulations (LES) (Hu et al, 2019;Long et al, 2020;Hu et al, 2021;Asnaghi et al, 2020;Long et al, 2019;Asnaghi et al, 2018). The form of acoustic analogy mostly employed for the prediction of noise from moving bodies is based on the solution of the Ffowcs William-Hawkings (FWH) acoustic analogy formulation (Ffowcs Willams, 1969), which has proven to be an effective and reliable numerical tool for sound radiation problems dominated by fluid/body interactions (Brentner and Farassat, 2003;Farassat and Brentner, 1988).…”

Computational prediction of underwater radiated noise of cavitating marine propellers: On the accuracy of semi-empirical models

“…Depending on how various turbulence length scales are modelled or resolved, applied CFD methods can be classified as (Li et al, 2018): RANS or Unsteady RANS if the flow is treated as unsteady (Sezen et al, 2021c,b,a;Lee et al, 2021;Ge et al, 2020;Yao et al, 2021;Melissaris et al, 2020;Wu et al, 2018;Peters et al, 2018;Huang et al, 2019b;Lidtke et al, 2019); Detached Eddy Simulations (DES) (Ku et al, 2021;Usta and Korkut, 2019;Long et al, 2021;Yilmaz et al, 2020;Sezen et al, 2021a;Sakamoto and Kamiirisa, 2018); and Large Eddy Simulations (LES) (Hu et al, 2019;Long et al, 2020;Hu et al, 2021;Asnaghi et al, 2020;Long et al, 2019;Asnaghi et al, 2018). The form of acoustic analogy mostly employed for the prediction of noise from moving bodies is based on the solution of the Ffowcs William-Hawkings (FWH) acoustic analogy formulation (Ffowcs Willams, 1969), which has proven to be an effective and reliable numerical tool for sound radiation problems dominated by fluid/body interactions (Brentner and Farassat, 2003;Farassat and Brentner, 1988).…”

Computational prediction of underwater radiated noise of cavitating marine propellers: On the accuracy of semi-empirical models

“…To investigate unsteady cavitation around a NACA0015 hydrofoil and its associated noise, Yu et al [20] combined a filter-based turbulence model with the Zwart-Gerbera-Belamri (ZGB) cavitation model. To predict hydrodynamic noise, caused by tip-vortex cavitation (TVC) of submarine propellers, Ku et al [21] employed delayed detached eddy simulation (DDES) with adaptive mesh refinement and the FW-H equation, and concluded that a higher pitch angle resulted in more noise. It has been reported by Testa [22] that an improved hydroacoustic formulation based on the standard FW-H equation can accurately predict noise magnitude and direction based on the emitted noise and sheet cavitation dynamics.…”

Investigation of cavitation noise using Eulerian-Lagrangian multiscale modeling

“…When the local pressure underwater is less than the vapor pressure, bubbles spill out of the water and cavitation occurs [2] , [3] , [4] , [5] . According to the generalized Bernoulli principle (where the flow velocity is high, the pressure is low), in engineering practice, this phenomenon mostly occurs in areas where water flows at a high speed, such as underwater propellers [6] , [7] , ship rudders [8] , water pumps [9] , [10] , valves [11] , [12] , right-angle pipes [13] , etc. Cavitation bubbles underwater undergo the process of bubble generation, expansion, contraction, collapse, and rebound [14] .…”

Manipulation of bubble collapse patterns near the wall of an adherent gas layer